Release v0.1.0-beta.2

Add TempCo integration tests
Implement TempCo characterisation test
2025-09-22 11:04:43 +00:00 · 2025-09-16 11:20:03 +00:00 · 2025-09-15 18:32:58 +00:00 · 2025-09-10 16:03:37 +00:00 · 2025-09-09 19:31:09 +00:00 · 2025-09-05 15:44:46 +00:00
80 changed files with 10134 additions and 500 deletions
--- a/CHANGELOG.md
+++ b/CHANGELOG.md
@@ -7,6 +7,109 @@ and this project adheres to [Semantic Versioning](https://semver.org/spec/v2.0.0
 ## [Unreleased]
 ## [0.1.0-beta.2] - 2025-12-03
 ### Added
 - Test Executive Framework (Sprint 14)
  - TestContext dataclass providing runtime context for tests
  - ITest abstract base class defining test interface
  - TestLogger for recording measurements, results, and events
  - LimitChecker for evaluating pass/fail against specification limits
  - TestRunner for orchestrating test execution
  - SQLite-based TestRepository for persisting test data
  - Parquet measurement storage for efficient time-series data
 - DVT Test Implementation (Sprint 15)
  - BaseDVTTest providing common test utilities
  - TempCo characterisation test (temperature coefficient measurement)
  - Temperature sweep with automatic thermal settling
  - Linear regression TempCo calculation (ppm/°C)
  - Comprehensive integration tests for end-to-end validation
 ### Technical
 - Test framework supports data logging, limit evaluation, and result persistence
 - TempCo test demonstrates full end-to-end workflow: configure instruments → sweep temperature → measure → calculate → evaluate
 - All framework and test components fully type-checked and linted
 ## [0.1.0-beta.1] - 2025-12-02
 ### Added
 - Hardware Abstraction Layer (HAL) with instrument interface protocols
  - IThermalChamber protocol with temperature control methods
  - IPowerSupply protocol with voltage/current control and measurement
  - IMultimeter protocol with DC voltage, current, and resistance measurement
 - Instrument drivers implementing HAL interfaces
  - ThermalChamberDriver implements IThermalChamber
  - PowerSupplyDriver implements IPowerSupply
  - MultimeterDriver implements IMultimeter
 - Instrument factory pattern for backend abstraction
  - InstrumentSet dataclass containing chamber, PSU, and DMM
  - InstrumentConfig for specifying backend (simulator/pyvisa) and connection details
  - InstrumentFactory.create() for creating instrument sets from configuration
 - Transport layer abstraction
  - Transport ABC defining connect/disconnect/read/write/query interface
  - TCPTransport implementation for TCP/IP connections
 - Comprehensive test suite for HAL (16 tests)
  - Interface implementation verification
  - Factory pattern testing with mocked backends
  - Configuration validation
 ### Changed
 - Drivers now explicitly inherit from interface ABCs for maximum type safety
 - Moved InstrumentServer to instruments/transport for better architecture
 ### Technical
 - ABC-based interfaces ensure compile-time interface compliance
 - Factory pattern enables seamless switching between simulated and real hardware
 - All HAL components fully type-checked with mypy strict mode
 ## [0.1.0-alpha.3] - 2025-12-02
 ### Added
 - Async TCP server for exposing virtual instruments over network
 - InstrumentServer class with multi-port, multi-client support
 - Line-based SCPI protocol (newline-terminated commands/responses)
 - SimulationServer wiring physics engine to all virtual instruments
 - CLI `serve` command to start simulation server with configurable ports
 - Integration tests for TCP server and instrument connectivity
 ### Infrastructure
 - SCPI foundation (Sprint 5): command parser with IEEE 488.2 support
 - Virtual instrument base class with command dispatch
 - Thermal chamber simulator (TEMP:SETPOINT, TEMP:ACTUAL?, TEMP:STAB?)
 - Power supply simulator (VOLT, CURR, OUTP, MEAS commands)
 - Multimeter simulator (MEAS:VOLT:DC?, MEAS:CURR:DC?, CONF, READ?)
 ## [0.1.0-alpha.2] - 2025-12-02
 ### Added
 - Streamlit dashboard for interactive physics visualisation
 - Real-time temperature charts (chamber, case, junction)
 - Current state metrics display (voltages, currents, power, temperatures)
 - Interactive controls in sidebar:
  - Temperature setpoint slider (-40°C to 125°C)
  - Input voltage slider (0-12V)
  - Load current slider (0-500mA)
  - Output enable toggle
  - Start/Stop/Reset simulation buttons
 - Self-heating demonstration panel with:
  - Junction-case and case-ambient temperature rise display
  - Power dissipation chart
  - Thermal coupling explanation
 ## [0.1.0-alpha.1] - 2025-12-02
 ### Added
 - Physics engine with thermal-electrical coupling
 - First-order thermal response calculations for chamber and case
 - Junction temperature calculation via thermal resistance (θ_jc)
 - Self-heating effects from power dissipation
 - LDO DUT model with temperature-dependent behaviour
  - Output voltage temperature coefficient (ppm/°C)
  - Quiescent current temperature coefficient
  - Dropout voltage temperature dependence
  - Power dissipation calculation
 - Comprehensive physics engine test suite (13 tests)
 ## [0.0.1] - 2025-12-01
 ### Added
@@ -26,9 +129,9 @@ and this project adheres to [Semantic Versioning](https://semver.org/spec/v2.0.0
 | Version | Date | Milestone |
 |---------|------|-----------|
 | 0.1.0 | TBD | MVP Complete |
-| 0.1.0-beta.2 | TBD | First DVT test runs |
+| 0.1.0-beta.2 | 2025-12-03 | First DVT test runs |
-| 0.1.0-beta.1 | TBD | HAL complete |
+| 0.1.0-beta.1 | 2025-12-02 | HAL complete |
-| 0.1.0-alpha.3 | TBD | Network ready |
+| 0.1.0-alpha.3 | 2025-12-02 | Network ready |
-| 0.1.0-alpha.2 | TBD | Visual demo |
+| 0.1.0-alpha.2 | 2025-12-02 | Visual demo |
-| 0.1.0-alpha.1 | TBD | Physics engine |
+| 0.1.0-alpha.1 | 2025-12-02 | Physics engine |
 | 0.0.1 | 2025-12-01 | Project scaffolding |
--- a/config/default.yaml
+++ b/config/default.yaml
@@ -0,0 +1,149 @@
 # py_dvt_ate Default Configuration
 # This file contains default settings for the DVT simulation platform.
 # Copy this file and modify values as needed for your environment.
 # =============================================================================
 # Instrument Configuration
 # =============================================================================
 instruments:
  # Backend selection: "simulator" or "pyvisa"
  # - simulator: Use virtual instruments with physics simulation (for development)
  # - pyvisa: Connect to real instruments via PyVISA (for production testing)
  backend: simulator
  # Simulator backend configuration
  # Used when backend=simulator. Virtual instruments are exposed as TCP servers.
  simulator:
    host: localhost
    thermal_chamber_port: 5001
    power_supply_port: 5002
    multimeter_port: 5003
  # PyVISA backend configuration
  # Used when backend=pyvisa. Provide VISA resource strings for real instruments.
  # Example: "TCPIP::192.168.1.10::5001::SOCKET"
  pyvisa:
    thermal_chamber: null
    power_supply: null
    multimeter: null
 # =============================================================================
 # Physics Simulation Parameters
 # =============================================================================
 physics:
  # Physics engine update rate (Hz)
  # Higher rates provide better accuracy but use more CPU.
  update_rate_hz: 100.0
  # Thermal model parameters
  thermal:
    # Chamber thermal time constant (seconds)
    # Time for chamber temperature to reach 63% of final value
    chamber_time_constant_s: 30.0
    # DUT case thermal time constant (seconds)
    # Time for case temperature to reach 63% of final value
    case_time_constant_s: 5.0
    # Junction-to-case thermal resistance (°C/W)
    # How much the junction heats above case per watt dissipated
    theta_jc: 15.0
    # Case-to-ambient thermal resistance (°C/W)
    # How much the case heats above ambient per watt dissipated
    theta_ca: 5.0
  # Thermal chamber behaviour
  chamber:
    # Maximum temperature ramp rate (°C/min)
    # Real chambers have limited heating/cooling rates
    ramp_rate_c_per_min: 10.0
    # Temperature stability window (°C)
    # Chamber is considered stable when within ±this value of setpoint
    stability_window_c: 0.5
    # Stability duration requirement (seconds)
    # Chamber must remain in stability window for this duration
    stability_time_s: 30.0
 # =============================================================================
 # DUT (Device Under Test) Configuration
 # =============================================================================
 dut:
  # DUT model type
  # Currently supported: "ldo"
  model: ldo
  # DUT model parameters
  parameters:
    # Nominal output voltage at 25°C (V)
    nominal_output_voltage: 3.3
    # Temperature coefficient (ppm/°C)
    # Voltage change per degree: ΔV = V₀ × tempco × ΔT / 1e6
    tempco_ppm_per_c: 50.0
    # Quiescent current at 25°C (µA)
    quiescent_current_ua: 50.0
    # Quiescent current temperature coefficient (per °C)
    # Iq change per degree: ΔIq = Iq₀ × tempco × ΔT
    quiescent_current_tempco: 0.003
    # Dropout voltage (V)
    # Minimum Vin-Vout differential for regulation
    dropout_voltage: 0.3
 # =============================================================================
 # Data Storage Configuration
 # =============================================================================
 data:
  # SQLite database path for test runs and results
  database_path: ./data/py_dvt_ate.db
  # Directory for measurement data files (Parquet format)
  measurements_dir: ./data/measurements
  # Directory for generated reports (PDF, HTML)
  reports_dir: ./data/reports
 # =============================================================================
 # Logging Configuration
 # =============================================================================
 logging:
  # Logging level: DEBUG, INFO, WARNING, ERROR, CRITICAL
  level: INFO
  # Log file path
  # Use null to disable file logging
  file: ./data/logs/py_dvt_ate.log
  # Log message format
  # Uses Python logging format strings
  format: "%(asctime)s - %(name)s - %(levelname)s - %(message)s"
 # =============================================================================
 # Dashboard Configuration (Streamlit)
 # =============================================================================
 dashboard:
  # Enable/disable the Streamlit dashboard
  enabled: true
  # Dashboard server port
  port: 8501
 # =============================================================================
 # API Configuration (Phase 2)
 # =============================================================================
 api:
  # Enable/disable the REST API server
  # Currently not implemented (Phase 2 feature)
  enabled: false
  # API server host
  # Use "0.0.0.0" to listen on all interfaces
  host: "0.0.0.0"
  # API server port
  port: 8000
--- a/docs/02_technical_specification.md
+++ b/docs/02_technical_specification.md
@@ -214,7 +214,7 @@ For **why** decisions were made, see `03_architecture_decisions.md`.
 ### 2.1 Directory Layout
 ```
-thermaulate/
+py_dvt_ate/
 ├── pyproject.toml              # Project metadata and dependencies
 ├── README.md                   # Project overview and quick start
 ├── CHANGELOG.md                # Version history
@@ -222,205 +222,163 @@ thermaulate/
 ├── docs/
 │   ├── 01_requirements.md              # Business Requirements
 │   ├── 02_technical_specification.md   # Technical Design (this doc)
-│   └── 03_architecture_decisions.md    # Architecture Decisions
+│   ├── 03_architecture_decisions.md    # Architecture Decisions
 │   └── 04_development_plan.md          # Sprint breakdown
 │
-├── src/
+├── src/py_dvt_ate/
-│   └── thermaulate/
+│   ├── __init__.py                     # Package version
 │       ├── __init__.py
 │   ├── py.typed                        # PEP 561 marker
 │   │
-│       ├── physics/                     # Physics simulation engine
+│   ├── instruments/                    # INSTRUMENT CONTROL (reusable)
 │   │   ├── __init__.py
-│       │   ├── engine.py                # Main physics loop
+│   │   ├── interfaces.py               # IThermalChamber, IPowerSupply, IMultimeter
-│       │   ├── thermal.py               # Thermal domain model
+│   │   ├── scpi.py                     # SCPI parser (shared protocol)
-│       │   ├── electrical.py            # Electrical domain model
+│   │   ├── factory.py                  # Creates instrument sets from config
-│       │   └── dut/
+│   │   ├── transport/                  # Connection layer
 │   │   │   ├── __init__.py
 │   │   │   ├── base.py                 # Transport protocol
 │   │   │   ├── tcp.py                  # TCP socket transport
 │   │   │   └── visa.py                 # PyVISA transport (future)
 │   │   └── drivers/                    # SCPI driver implementations
 │   │       ├── __init__.py
-│       │       ├── base.py              # DUT base class
+│   │       ├── base.py                 # Base driver
-│       │       └── ldo.py               # LDO voltage regulator model
+│   │       ├── chamber.py              # Thermal chamber driver
 │   │       ├── power_supply.py         # PSU driver
 │   │       └── multimeter.py           # DMM driver
 │   │
-│       ├── instruments/                 # Virtual instrument implementations
+│   ├── simulation/                     # PHYSICS SIMULATION (dev/test only)
 │   │   ├── __init__.py
-│       │   ├── base.py                  # Instrument base class
+│   │   ├── server.py                   # TCP server hosting virtual instruments
-│       │   ├── scpi_parser.py           # SCPI command parser
+│   │   ├── physics/                    # Physics engine
-│       │   ├── thermal_chamber.py       # Thermal chamber simulator
+│   │   │   ├── __init__.py
-│       │   ├── power_supply.py          # Power supply simulator
+│   │   │   ├── engine.py               # Main simulation loop
-│       │   └── multimeter.py            # DMM simulator
+│   │   │   ├── thermal.py              # Thermal calculations
 │   │   │   └── models/                 # DUT models
 │   │   │       ├── __init__.py
 │   │   │       ├── base.py             # DUT protocol
 │   │   │       └── ldo.py              # LDO model
 │   │   └── virtual/                    # Virtual instrument implementations
 │   │       ├── __init__.py
 │   │       ├── base.py                 # Base virtual instrument
 │   │       ├── chamber.py              # Virtual thermal chamber
 │   │       ├── power_supply.py         # Virtual PSU
 │   │       └── multimeter.py           # Virtual DMM
 │   │
-│       ├── server/                      # Simulation server
+│   ├── framework/                      # TEST FRAMEWORK (reusable)
 │   │   ├── __init__.py
-│       │   ├── tcp_server.py            # Async TCP server
+│   │   ├── runner.py                   # Test sequencer
-│       │   └── main.py                  # Server entry point
+│   │   ├── context.py                  # Runtime context
 │   │   ├── logger.py                   # Measurement logging
 │   │   ├── limits.py                   # Pass/fail evaluation
 │   │   └── models.py                   # Framework models
 │   │
-│       ├── transport/                   # Communication layer
+│   ├── tests/                          # DVT TEST IMPLEMENTATIONS
 │   │   ├── __init__.py
-│       │   ├── base.py                  # Transport protocol
+│   │   ├── base.py                     # Base test class
-│       │   ├── tcp.py                   # TCP/IP implementation
+│   │   ├── thermal/                    # Thermal characterisation tests
-│       │   └── async_tcp.py             # Async TCP implementation
+│   │   │   ├── __init__.py
-│       │
+│   │   │   └── tempco.py               # Temperature coefficient test
-│       ├── drivers/                     # Instrument SCPI drivers
+│   │   └── electrical/                 # Electrical characterisation tests
 │   │       ├── __init__.py
 │       │   ├── base.py                  # Driver base class
 │       │   ├── thermal_chamber.py       # Chamber SCPI driver
 │       │   ├── power_supply.py          # PSU SCPI driver
 │       │   └── multimeter.py            # DMM SCPI driver
 │       │
 │       ├── hal/                         # Hardware Abstraction Layer
 │       │   ├── __init__.py
 │       │   ├── interfaces.py            # Protocol definitions
 │       │   ├── factory.py               # Instrument factory
 │       │   └── impl/                    # HAL implementations
 │       │       ├── __init__.py
 │       │       ├── thermal_chamber.py
 │       │       ├── power_supply.py
 │       │       └── multimeter.py
 │       │
 │       ├── executive/                   # Test execution framework
 │       │   ├── __init__.py
 │       │   ├── sequencer.py             # Test sequencer
 │       │   ├── context.py               # Test context
 │       │   ├── logger.py                # Test logger
 │       │   ├── limits.py                # Limit checker
 │       │   └── models.py                # Domain models
 │       │
 │       ├── tests/                       # DVT test implementations
 │       │   ├── __init__.py
 │       │   ├── base.py                  # Test base class
 │       │   ├── tempco.py                # TempCo characterisation
 │   │       └── load_regulation.py      # Load regulation test
 │   │
-│       ├── data/                        # Data persistence
+│   ├── data/                           # DATA PERSISTENCE (shared)
 │   │   ├── __init__.py
 │   │   ├── repository.py               # Data access layer
-│       │   ├── models.py                # Data models
+│   │   └── models.py                   # Data models
 │       │   └── migrations/              # Schema migrations
 │   │
-│       ├── reporting/                   # Report generation (Phase 3)
+│   ├── reporting/                      # REPORT GENERATION (standalone)
 │   │   ├── __init__.py
 │   │   ├── generator.py                # Report generator
 │       │   ├── pdf.py                   # PDF output
 │       │   ├── html.py                  # HTML output
 │   │   └── templates/                  # Report templates
 │   │
-│       ├── api/                         # REST API (Phase 2)
+│   └── app/                            # APPLICATION ENTRY POINTS
 │       │   ├── __init__.py
 │       │   ├── main.py                  # FastAPI app
 │       │   └── routes/
 │       │       ├── __init__.py
 │       │       ├── instruments.py
 │       │       ├── tests.py
 │       │       └── runs.py
 │       │
 │       ├── dashboard/                   # Streamlit dashboard
 │       │   ├── __init__.py
 │       │   ├── app.py                   # Main Streamlit app
 │       │   ├── pages/                   # Multi-page app
 │       │   │   ├── 01_instruments.py
 │       │   │   ├── 02_run_test.py
 │       │   │   └── 03_results.py
 │       │   └── components/              # Reusable UI components
 │       │       ├── __init__.py
 │       │       └── instrument_panel.py
 │       │
 │       ├── cli/                         # Command-line interface
 │       │   ├── __init__.py
 │       │   └── main.py                  # Typer CLI app
 │       │
 │       └── config/                      # Configuration handling
 │       ├── __init__.py
-│           ├── models.py                # Pydantic config models
+│       ├── cli.py                      # Command-line interface
-│           └── loader.py                # Config file loader
+│       ├── config.py                   # YAML loading
 │       └── dashboard/                  # Streamlit dashboard
 │           ├── __init__.py
 │           └── app.py                  # Main Streamlit app
 │
-├── tests/                               # Test suite
+├── tests/                              # pytest test suite
 │   ├── conftest.py                     # pytest fixtures
-│   ├── unit/
+│   ├── unit/                           # Unit tests
-│   │   ├── test_physics_engine.py
+│   └── integration/                    # Integration tests
 │   │   ├── test_scpi_parser.py
 │   │   ├── test_thermal_model.py
 │   │   └── ...
 │   └── integration/
 │       ├── test_instrument_communication.py
 │       ├── test_tempco_sequence.py
 │       └── ...
 │
 ├── config/                             # Configuration files
-│   ├── default.yaml                     # Default configuration
+│   └── default.yaml                    # Default configuration
 │   └── example_pyvisa.yaml              # Example for real hardware
 │
-├── docker/
+└── docker/                             # Docker deployment
-│   ├── Dockerfile.server                # Simulation server image
+    ├── Dockerfile.server               # Simulation server image
-│   ├── Dockerfile.app                   # Test application image
+    ├── Dockerfile.app                  # Test application image
-│   └── docker-compose.yml               # Full stack orchestration
+    └── docker-compose.yml              # Full stack orchestration
 │
 └── scripts/
    ├── demo.py                          # Demo script
    └── run_tempco.py                    # Example test execution
 ```
 ### 2.2 Package Dependencies
 ```
-thermaulate/
+Dependency Graph:
 ├── cli/           ──────────────────────────────────────────────┐
 ├── api/           ──────────────────────────────────────────────┤
 ├── dashboard/     ──────────────────────────────────────────────┤
 │                                                                 │
 │   ┌─────────────────────────────────────────────────────────┐  │
 │   │                    PRESENTATION                          │  │
 │   └─────────────────────────────────────────────────────────┘  │
 │                              │                                  │
 │                              ▼                                  │
 ├── executive/     ◄───────────────────────────────────────────────┤
 ├── tests/         ◄───────────────────────────────────────────────┤
 ├── reporting/     ◄───────────────────────────────────────────────┤
 │                                                                 │
 │   ┌─────────────────────────────────────────────────────────┐  │
 │   │                    APPLICATION                           │  │
 │   └─────────────────────────────────────────────────────────┘  │
 │                              │                                  │
 │                              ▼                                  │
 ├── hal/interfaces ◄───────────────────────────────────────────────┤
 │                                                                 │
 │   ┌─────────────────────────────────────────────────────────┐  │
 │   │                    DOMAIN (Abstractions)                 │  │
 │   └─────────────────────────────────────────────────────────┘  │
 │                              │                                  │
 │                    implements│                                  │
 │                              ▼                                  │
 ├── hal/impl       ◄───────────────────────────────────────────────┤
 ├── drivers/       ◄───────────────────────────────────────────────┤
 ├── transport/     ◄───────────────────────────────────────────────┤
 ├── data/          ◄───────────────────────────────────────────────┤
 │                                                                 │
 │   ┌─────────────────────────────────────────────────────────┐  │
 │   │                    INFRASTRUCTURE                        │  │
 │   └─────────────────────────────────────────────────────────┘  │
 │                                                                 │
 └─────────────────────────────────────────────────────────────────┘
-SIMULATION SERVER (Separate Process):
+app/ ──────────────▶ framework/ ──────────────▶ instruments/
-├── physics/       ◄─── Pure domain logic, no external dependencies
+  │                      │                           │
-├── instruments/   ◄─── Depends on physics
+  │                      ▼                           │
-└── server/        ◄─── Depends on instruments
+  │                   data/ ◀────────────────────────┘
  │                      ▲
  ▼                      │
 reporting/ ──────────────┘
 simulation/ ─────────────────────────────────▶ instruments/
 Key:
 - app/         : CLI, dashboard, config loading (PRESENTATION)
 - framework/   : Test runner, logger, limits (APPLICATION)
 - instruments/ : Interfaces, drivers, transport, SCPI (DOMAIN)
 - data/        : Persistence layer (INFRASTRUCTURE)
 - reporting/   : Report generation (standalone)
 - simulation/  : Physics engine, virtual instruments (DEVELOPMENT)
 ```
 ---
 ## 3. Module Specifications
-### 3.1 Physics Module
+### 3.1 Instruments Package
-**Responsibility**: Simulate coupled thermal-electrical behaviour.
+**Responsibility**: Everything about talking to lab instruments.
 **Key Components**:
 | Component | File | Purpose |
 |-----------|------|---------|
-| PhysicsEngine | `engine.py` | Main simulation loop, state management |
+| Interfaces | `instruments/interfaces.py` | IThermalChamber, IPowerSupply, IMultimeter protocols |
-| ThermalModel | `thermal.py` | Heat transfer calculations |
+| SCPIParser | `instruments/scpi.py` | Parse SCPI command strings |
-| ElectricalModel | `electrical.py` | Current/voltage relationships |
+| Factory | `instruments/factory.py` | Create instrument sets from config |
-| DUTBase | `dut/base.py` | Abstract DUT interface |
+| Transport | `instruments/transport/` | TCP, VISA connection layer |
-| LDOModel | `dut/ldo.py` | LDO voltage regulator implementation |
+| Drivers | `instruments/drivers/` | SCPI command implementations |
 **Command Processing Flow**:
 ```
 High-level call → Driver → SCPI command → Transport → Instrument
 ```
 ---
 ### 3.2 Simulation Package
 **Responsibility**: Physics simulation for development without real hardware.
 **Key Components**:
 | Component | File | Purpose |
 |-----------|------|---------|
 | Server | `simulation/server.py` | TCP server hosting virtual instruments |
 | PhysicsEngine | `simulation/physics/engine.py` | Main simulation loop |
 | ThermalModel | `simulation/physics/thermal.py` | Heat transfer calculations |
 | DUTBase | `simulation/physics/models/base.py` | Abstract DUT interface |
 | LDOModel | `simulation/physics/models/ldo.py` | LDO voltage regulator model |
 | VirtualChamber | `simulation/virtual/chamber.py` | Virtual thermal chamber |
 | VirtualPSU | `simulation/virtual/power_supply.py` | Virtual power supply |
 | VirtualDMM | `simulation/virtual/multimeter.py` | Virtual multimeter |
 **State Management**:
 - Engine maintains global simulation time
@@ -429,212 +387,186 @@ SIMULATION SERVER (Separate Process):
 ---
-### 3.2 Instruments Module
+### 3.3 Framework Package
-**Responsibility**: SCPI-compliant virtual instrument behaviour.
+**Responsibility**: Test execution infrastructure.
 **Key Components**:
 | Component | File | Purpose |
 |-----------|------|---------|
-| InstrumentBase | `base.py` | Common instrument functionality |
+| TestRunner | `framework/runner.py` | Sequences test steps |
-| SCPIParser | `scpi_parser.py` | Parse SCPI command strings |
+| TestContext | `framework/context.py` | Runtime context |
-| ThermalChamberSim | `thermal_chamber.py` | Chamber simulation |
+| TestLogger | `framework/logger.py` | Measurement logging |
-| PowerSupplySim | `power_supply.py` | PSU simulation |
+| LimitChecker | `framework/limits.py` | Pass/fail evaluation |
-| MultimeterSim | `multimeter.py` | DMM simulation |
+| Models | `framework/models.py` | TestStatus, TestResult, etc. |
 **Command Processing Flow**:
 ```
 SCPI String → Parser → Command Object → Instrument Handler → Response
 ```
 ---
-### 3.3 Transport Module
+### 3.4 Data Package
-**Responsibility**: Low-level communication.
+**Responsibility**: Data persistence for test results.
 **Key Components**:
 | Component | File | Purpose |
 |-----------|------|---------|
-| Transport Protocol | `base.py` | Abstract transport interface |
+| Repository | `data/repository.py` | Data access layer |
-| TCPTransport | `tcp.py` | Synchronous TCP implementation |
+| Models | `data/models.py` | TestRun, Measurement dataclasses |
 | AsyncTCPTransport | `async_tcp.py` | Async TCP implementation |
 ---
-### 3.4 Drivers Module
+### 3.5 Reporting Package
-**Responsibility**: Instrument-specific SCPI command sets.
+**Responsibility**: Report generation from stored data.
 **Key Components**:
 | Component | File | Purpose |
 |-----------|------|---------|
-| DriverBase | `base.py` | Common driver functionality |
+| Generator | `reporting/generator.py` | Creates reports from data |
-| ThermalChamberDriver | `thermal_chamber.py` | Chamber SCPI commands |
+| Templates | `reporting/templates/` | Report templates |
 | PowerSupplyDriver | `power_supply.py` | PSU SCPI commands |
 | MultimeterDriver | `multimeter.py` | DMM SCPI commands |
 ---
-### 3.5 HAL Module
+### 3.6 App Package
-**Responsibility**: Hardware abstraction interfaces.
+**Responsibility**: Application entry points.
 **Key Components**:
 | Component | File | Purpose |
 |-----------|------|---------|
-| Protocols | `interfaces.py` | Abstract interfaces |
+| CLI | `app/cli.py` | Command-line interface (Typer) |
-| InstrumentFactory | `factory.py` | Creates instrument sets from config |
+| Config | `app/config.py` | YAML loading, instance creation |
-| HAL Implementations | `impl/*.py` | Concrete HAL classes |
+| Dashboard | `app/dashboard/app.py` | Streamlit application |
 ---
 ### 3.6 Executive Module
 **Responsibility**: Test execution orchestration.
 **Key Components**:
 | Component | File | Purpose |
 |-----------|------|---------|
 | TestSequencer | `sequencer.py` | Run test sequences |
 | TestContext | `context.py` | Runtime context |
 | TestLogger | `logger.py` | Measurement logging |
 | LimitChecker | `limits.py` | Pass/fail evaluation |
 | Domain Models | `models.py` | Measurement, Result, etc. |
 ---
 ### 3.7 Dashboard Module
 **Responsibility**: Real-time visualisation via Streamlit.
 **Key Components**:
 | Component | File | Purpose |
 |-----------|------|---------|
 | Main App | `app.py` | Streamlit application entry point |
 | Instruments Page | `pages/01_instruments.py` | Live instrument status |
 | Run Test Page | `pages/02_run_test.py` | Test execution interface |
 | Results Page | `pages/03_results.py` | Historical results viewer |
 | Instrument Panel | `components/instrument_panel.py` | Reusable instrument display |
 ---
 ## 4. Interface Definitions
-### 4.1 HAL Interfaces
+### 4.1 Instrument Interfaces
 ```python
-# thermaulate/hal/interfaces.py
+# py_dvt_ate/instruments/interfaces.py
-from typing import Protocol, runtime_checkable
+from abc import ABC, abstractmethod
@runtime_checkable
-class IThermalChamber(Protocol):
+class IThermalChamber(ABC):
    """Hardware abstraction for thermal chambers."""
    @abstractmethod
    def set_temperature(self, setpoint: float) -> None:
-        """Set target temperature in degrees Celsius."""
+        """[docstring]"""  
-        ...
+        pass
    @abstractmethod
    def get_temperature(self) -> float:
-        """Get current actual temperature in degrees Celsius."""
+        """[docstring]"""  
-        ...
+        pass
    @abstractmethod
    def get_setpoint(self) -> float:
-        """Get current temperature setpoint."""
+        """[docstring]"""  
-        ...
+        pass
    @abstractmethod
    def is_stable(self) -> bool:
-        """Check if temperature has stabilised at setpoint."""
+        """[docstring]"""  
-        ...
+        pass
    @abstractmethod
    def wait_until_stable(
        self,
        timeout: float = 300.0,
        poll_interval: float = 1.0
    ) -> bool:
-        """
+        """[docstring]"""  
-        Block until temperature stabilises or timeout.
+        pass
        Returns:
            True if stable, False if timeout
        """
        ...
    @abstractmethod
    def set_ramp_rate(self, rate: float) -> None:
-        """Set temperature ramp rate in degrees C per minute."""
+        """[docstring]"""  
-        ...
+        pass
@runtime_checkable
-class IPowerSupply(Protocol):
+class IPowerSupply(ABC):
    """Hardware abstraction for programmable power supplies."""
    @abstractmethod
    def set_voltage(self, channel: int, voltage: float) -> None:
-        """Set output voltage for specified channel."""
+        """[docstring]"""  
-        ...
+        pass
    @abstractmethod
    def get_voltage(self, channel: int) -> float:
-        """Get voltage setpoint for specified channel."""
+        """[docstring]"""  
-        ...
+        pass
    @abstractmethod
    def set_current_limit(self, channel: int, current: float) -> None:
-        """Set current limit for specified channel."""
+        """[docstring]"""  
-        ...
+        pass
    @abstractmethod
    def get_current_limit(self, channel: int) -> float:
-        """Get current limit for specified channel."""
+        """[docstring]"""  
-        ...
+        pass
    @abstractmethod
    def measure_voltage(self, channel: int) -> float:
-        """Measure actual output voltage."""
+        """[docstring]"""  
-        ...
+        pass
    @abstractmethod
    def measure_current(self, channel: int) -> float:
-        """Measure actual output current."""
+        """[docstring]"""  
-        ...
+        pass
    @abstractmethod
    def enable_output(self, channel: int, enable: bool) -> None:
-        """Enable or disable channel output."""
+        """[docstring]"""  
-        ...
+        pass
    @abstractmethod
    def is_output_enabled(self, channel: int) -> bool:
-        """Check if channel output is enabled."""
+        """[docstring]"""  
-        ...
+        pass
@runtime_checkable
-class IMultimeter(Protocol):
+class IMultimeter(ABC):
    """Hardware abstraction for digital multimeters."""
    @abstractmethod
    def measure_dc_voltage(self, range: str = "AUTO") -> float:
-        """Measure DC voltage. Range: AUTO, 0.1, 1, 10, 100, 1000."""
+        """[docstring]"""  
-        ...
+        pass
    @abstractmethod
    def measure_dc_current(self, range: str = "AUTO") -> float:
-        """Measure DC current."""
+        """[docstring]"""  
-        ...
+        pass
    @abstractmethod
    def measure_resistance(self, range: str = "AUTO") -> float:
-        """Measure resistance."""
+        """[docstring]"""  
-        ...
+        pass
    @abstractmethod
    def set_integration_time(self, nplc: float) -> None:
-        """Set integration time in power line cycles (0.1 to 100)."""
+        """[docstring]"""  
-        ...
+        pass
@runtime_checkable
-class ITestLogger(Protocol):
+class ITestLogger(ABC):
    """Abstraction for test data logging."""
    @abstractmethod
    def log_measurement(
        self,
        parameter: str,
@@ -642,9 +574,10 @@ class ITestLogger(Protocol):
        unit: str,
        conditions: dict[str, float] | None = None
    ) -> None:
-        """Log a single measurement."""
+        """[docstring]"""  
-        ...
+        pass
    @abstractmethod
    def log_result(
        self,
        parameter: str,
@@ -653,60 +586,67 @@ class ITestLogger(Protocol):
        lower_limit: float | None = None,
        upper_limit: float | None = None
    ) -> None:
-        """Log a test result with optional limits."""
+        """[docstring]"""  
-        ...
+        pass
    @abstractmethod
    def log_event(self, message: str, level: str = "INFO") -> None:
-        """Log a test event or message."""
+        """[docstring]"""  
-        ...
+        pass
 ```
 ### 4.2 Transport Interface
 ```python
-# thermaulate/transport/base.py
+# py_dvt_ate/instruments/transport/base.py
-from typing import Protocol
+from abc import ABC, abstractmethod
-class Transport(Protocol):
+class Transport(ABC):
    """Abstract transport interface for instrument communication."""
    @abstractmethod
    def connect(self) -> None:
-        """Establish connection to instrument."""
+        """[docstring]"""  
-        ...
+        pass
    @abstractmethod
    def disconnect(self) -> None:
-        """Close connection to instrument."""
+        """[docstring]"""  
-        ...
+        pass
    @abstractmethod
    def write(self, command: str) -> None:
-        """Send command to instrument."""
+        """[docstring]"""  
-        ...
+        pass
    @abstractmethod
    def read(self, timeout: float | None = None) -> str:
-        """Read response from instrument."""
+        """[docstring]"""  
-        ...
+        pass
    @abstractmethod
    def query(self, command: str, timeout: float | None = None) -> str:
-        """Send command and read response."""
+        """[docstring]"""  
-        ...
+        pass
    @property
    @abstractmethod
    def is_connected(self) -> bool:
-        """Check if connection is active."""
+        """[docstring]"""  
-        ...
+        pass
 ```
 ### 4.3 Test Interface
 ```python
-# thermaulate/executive/models.py
+# py_dvt_ate/framework/models.py
 from dataclasses import dataclass, field
 from datetime import datetime
 from enum import Enum
-from typing import Protocol
+from abc import ABC, abstractmethod
 from uuid import UUID
@@ -757,33 +697,36 @@ class TestContext:
    config: dict
-class ITest(Protocol):
+class ITest(ABC):
    """Interface for test implementations."""
    @property
    @abstractmethod
    def name(self) -> str:
-        """Test name identifier."""
+        """[docstring]"""  
-        ...
+        pass
    @property
    @abstractmethod
    def description(self) -> str:
-        """Human-readable test description."""
+        """[docstring]"""  
-        ...
+        pass
    @abstractmethod
    def execute(self, context: TestContext) -> TestStatus:
-        """Execute the test, return status."""
+        """[docstring]"""  
-        ...
+        pass
 ```
 ### 4.4 Factory Interface
 ```python
-# thermaulate/hal/factory.py
+# py_dvt_ate/instruments/factory.py
 from dataclasses import dataclass
 from typing import Literal
-from thermaulate.hal.interfaces import IThermalChamber, IPowerSupply, IMultimeter
+from py_dvt_ate.instruments.interfaces import IThermalChamber, IPowerSupply, IMultimeter
@dataclass
@@ -827,22 +770,19 @@ class InstrumentFactory:
    @staticmethod
    def _create_simulated(config: InstrumentConfig) -> InstrumentSet:
        """Create simulated instruments."""
-        from thermaulate.transport.tcp import TCPTransport
+        from py_dvt_ate.instruments.transport.tcp import TCPTransport
-        from thermaulate.drivers.thermal_chamber import ThermalChamberDriver
+        from py_dvt_ate.instruments.drivers.chamber import ThermalChamberDriver
-        from thermaulate.drivers.power_supply import PowerSupplyDriver
+        from py_dvt_ate.instruments.drivers.power_supply import PowerSupplyDriver
-        from thermaulate.drivers.multimeter import MultimeterDriver
+        from py_dvt_ate.instruments.drivers.multimeter import MultimeterDriver
        from thermaulate.hal.impl.thermal_chamber import ThermalChamberHAL
        from thermaulate.hal.impl.power_supply import PowerSupplyHAL
        from thermaulate.hal.impl.multimeter import MultimeterHAL
        chamber_transport = TCPTransport(config.simulator_host, config.chamber_port)
        psu_transport = TCPTransport(config.simulator_host, config.psu_port)
        dmm_transport = TCPTransport(config.simulator_host, config.dmm_port)
        return InstrumentSet(
-            chamber=ThermalChamberHAL(ThermalChamberDriver(chamber_transport)),
+            chamber=ThermalChamberDriver(chamber_transport),
-            psu=PowerSupplyHAL(PowerSupplyDriver(psu_transport)),
+            psu=PowerSupplyDriver(psu_transport),
-            dmm=MultimeterHAL(MultimeterDriver(dmm_transport)),
+            dmm=MultimeterDriver(dmm_transport),
        )
    @staticmethod
@@ -954,7 +894,7 @@ All instruments implement these standard commands:
 ### 5.5 SCPI Parser Specification
 ```python
-# thermaulate/instruments/scpi_parser.py
+# py_dvt_ate/instruments/scpi.py
 from dataclasses import dataclass
@@ -1071,7 +1011,7 @@ P_diss = (V_in - V_out) × I_load + V_in × I_q
 ### 6.3 Physics Engine Implementation
 ```python
-# thermaulate/physics/engine.py
+# py_dvt_ate/simulation/physics/engine.py
 from dataclasses import dataclass
@@ -1256,32 +1196,36 @@ Schema:
 ### 7.3 Data Repository Interface
 ```python
-# thermaulate/data/repository.py
+# py_dvt_ate/data/repository.py (interface)
-from typing import Protocol
+from abc import ABC, abstractmethod
 from uuid import UUID
-class ITestRepository(Protocol):
+class ITestRepository(ABC):
    """Repository interface for test data."""
    @abstractmethod
    def create_run(
        self,
        test_name: str,
        config: dict,
        operator: str | None = None
    ) -> UUID:
-        """Create a new test run, return its ID."""
+        """[docstring]"""  
-        ...
+        pass
    @abstractmethod
    def update_run_status(self, run_id: UUID, status: str) -> None:
-        """Update test run status."""
+        """[docstring]"""  
-        ...
+        pass
    @abstractmethod
    def complete_run(self, run_id: UUID, status: str) -> None:
-        """Mark test run as complete with final status."""
+        """[docstring]"""  
-        ...
+        pass
    @abstractmethod
    def save_result(
        self,
        run_id: UUID,
@@ -1291,28 +1235,32 @@ class ITestRepository(Protocol):
        lower_limit: float | None = None,
        upper_limit: float | None = None
    ) -> None:
-        """Save a test result."""
+        """[docstring]"""  
-        ...
+        pass
    @abstractmethod
    def save_measurements(
        self,
        run_id: UUID,
        measurements: list["Measurement"]
    ) -> None:
-        """Save batch of measurements to Parquet."""
+        """[docstring]"""  
-        ...
+        pass
    @abstractmethod
    def get_run(self, run_id: UUID) -> "TestRun":
-        """Get test run by ID."""
+        """[docstring]"""  
-        ...
+        pass
    @abstractmethod
    def get_results(self, run_id: UUID) -> list["TestResult"]:
-        """Get all results for a test run."""
+        """[docstring]"""  
-        ...
+        pass
    @abstractmethod
    def get_measurements_dataframe(self, run_id: UUID):
-        """Get measurements as pandas DataFrame."""
+        """[docstring]"""  
-        ...
+        pass
 ```
 ---
@@ -1366,14 +1314,14 @@ dut:
 # Data storage paths
 data:
-  database_path: "./data/thermaulate.db"
+  database_path: "./data/py_dvt_ate.db"
  measurements_dir: "./data/measurements"
  reports_dir: "./data/reports"
 # Logging configuration
 logging:
  level: INFO
-  file: "./data/logs/thermaulate.log"
+  file: "./data/logs/py_dvt_ate.log"
  format: "%(asctime)s - %(name)s - %(levelname)s - %(message)s"
 # Dashboard (Streamlit)
@@ -1391,7 +1339,7 @@ api:
 ### 8.2 Pydantic Configuration Models
 ```python
-# thermaulate/config/models.py
+# py_dvt_ate/app/config.py (config models)
 from pydantic import BaseModel, Field
 from typing import Literal
@@ -1449,14 +1397,14 @@ class DUTConfig(BaseModel):
 class DataConfig(BaseModel):
-    database_path: str = "./data/thermaulate.db"
+    database_path: str = "./data/py_dvt_ate.db"
    measurements_dir: str = "./data/measurements"
    reports_dir: str = "./data/reports"
 class LoggingConfig(BaseModel):
    level: str = "INFO"
-    file: str = "./data/logs/thermaulate.log"
+    file: str = "./data/logs/py_dvt_ate.log"
    format: str = "%(asctime)s - %(name)s - %(levelname)s - %(message)s"
@@ -1612,7 +1560,7 @@ class AppConfig(BaseModel):
 ```toml
 [project]
-name = "thermaulate"
+name = "py_dvt_ate"
 version = "0.1.0"
 description = "Coupled Physics DVT Simulation Platform"
 requires-python = ">=3.11"
@@ -1648,9 +1596,9 @@ dev = [
 ]
 [project.scripts]
-thermaulate = "thermaulate.cli.main:app"
+py_dvt_ate = "py_dvt_ate.cli.main:app"
-thermaulate-server = "thermaulate.server.main:main"
+py_dvt_ate-server = "py_dvt_ate.server.main:main"
-thermaulate-dashboard = "thermaulate.dashboard.app:main"
+py_dvt_ate-dashboard = "py_dvt_ate.dashboard.app:main"
 [build-system]
 requires = ["hatchling"]
--- a/docs/04_development_plan.md
+++ b/docs/04_development_plan.md
@@ -38,7 +38,7 @@ Each sprint is ~1-2 days of work, producing demonstrable progress.
 **Vertical Slice Strategy:**
 - Sprints 1-3: Foundation + Physics Engine (the core simulation)
 - Sprint 4: Dashboard (see the physics working!)
- Sprints 5-11: Infrastructure/Plumbing (SCPI, TCP, HAL)
+- Sprints 5-11: Infrastructure/Plumbing (SCPI, TCP, Instruments)
 - Sprints 12-17: Test Framework, CLI, Polish
 ---
@@ -79,20 +79,18 @@ Each sprint is ~1-2 days of work, producing demonstrable progress.
 **Goal:** Define physics interfaces and data structures.
 ### Task 2.1: Define thermal state dataclasses
- Create src/py_dvt_ate/physics/__init__.py
+- Create src/py_dvt_ate/simulation/physics/models.py
 - Create src/py_dvt_ate/physics/models.py
 - Define ThermalState (frozen dataclass)
 - Define ElectricalState (frozen dataclass)
 - **Commit:** "Add physics state dataclasses"
 ### Task 2.2: Define DUT base protocol
- Create src/py_dvt_ate/physics/dut/__init__.py
+- Create src/py_dvt_ate/simulation/physics/models/base.py
 - Create src/py_dvt_ate/physics/dut/base.py
 - Define DUTModel Protocol with method signatures
 - **Commit:** "Add DUT model protocol"
 ### Task 2.3: Create physics engine stub
- Create src/py_dvt_ate/physics/engine.py
+- Create src/py_dvt_ate/simulation/physics/engine.py
 - Define PhysicsEngine class with stub methods
 - Methods return placeholder values
 - **Commit:** "Add physics engine stub"
@@ -109,13 +107,13 @@ Each sprint is ~1-2 days of work, producing demonstrable progress.
 **Goal:** Implement working physics simulation.
 ### Task 3.1: Implement thermal calculations
- Create src/py_dvt_ate/physics/thermal.py
+- Create src/py_dvt_ate/simulation/physics/thermal.py
 - Implement first-order thermal response calculations
 - Pure functions, no state
 - **Commit:** "Implement thermal calculation functions"
 ### Task 3.2: Implement LDO DUT model
- Create src/py_dvt_ate/physics/dut/ldo.py
+- Create src/py_dvt_ate/simulation/physics/models/ldo.py
 - Implement LDOModel class
 - Temperature-dependent Vout, Iq calculations
 - Power dissipation calculation
@@ -140,8 +138,8 @@ Each sprint is ~1-2 days of work, producing demonstrable progress.
 **Goal:** Visualise physics engine directly - see something working!
 ### Task 4.1: Create dashboard app skeleton
- Create src/py_dvt_ate/dashboard/__init__.py
+- Create src/py_dvt_ate/app/dashboard/__init__.py
- Create src/py_dvt_ate/dashboard/app.py
+- Create src/py_dvt_ate/app/dashboard/app.py
 - Basic Streamlit page with title
 - **Commit:** "Add Streamlit dashboard skeleton"
@@ -173,7 +171,7 @@ Each sprint is ~1-2 days of work, producing demonstrable progress.
 ### Task 5.1: Define SCPI command dataclass
 - Create src/py_dvt_ate/instruments/__init__.py
- Create src/py_dvt_ate/instruments/scpi_parser.py
+- Create src/py_dvt_ate/instruments/scpi.py
 - Define SCPICommand dataclass
 - **Commit:** "Add SCPI command dataclass"
@@ -196,13 +194,13 @@ Each sprint is ~1-2 days of work, producing demonstrable progress.
 **Goal:** Create first virtual instrument.
 ### Task 6.1: Define instrument base class
- Create src/py_dvt_ate/instruments/base.py
+- Create src/py_dvt_ate/simulation/virtual/base.py
 - Define BaseInstrument with common functionality
 - Command dispatch mechanism
 - **Commit:** "Add base instrument class"
 ### Task 6.2: Create thermal chamber simulator stub
- Create src/py_dvt_ate/instruments/thermal_chamber.py
+- Create src/py_dvt_ate/simulation/virtual/chamber.py
 - Define ThermalChamberSim class
 - Stub SCPI command handlers
 - **Commit:** "Add thermal chamber simulator stub"
@@ -224,7 +222,7 @@ Each sprint is ~1-2 days of work, producing demonstrable progress.
 **Goal:** Complete instrument simulators.
 ### Task 7.1: Create power supply simulator
- Create src/py_dvt_ate/instruments/power_supply.py
+- Create src/py_dvt_ate/simulation/virtual/power_supply.py
 - Implement PSU SCPI commands
 - VOLT, CURR, OUTP, MEAS commands
 - **Commit:** "Add power supply simulator"
@@ -234,7 +232,7 @@ Each sprint is ~1-2 days of work, producing demonstrable progress.
 - **Commit:** "Add power supply simulator tests"
 ### Task 7.3: Create DMM simulator
- Create src/py_dvt_ate/instruments/multimeter.py
+- Create src/py_dvt_ate/simulation/virtual/multimeter.py
 - Implement DMM SCPI commands
 - MEAS:VOLT:DC?, CONF commands
 - **Commit:** "Add multimeter simulator"
@@ -250,8 +248,8 @@ Each sprint is ~1-2 days of work, producing demonstrable progress.
 **Goal:** Expose instruments over network.
 ### Task 8.1: Create async TCP server foundation
- Create src/py_dvt_ate/server/__init__.py
+- Create src/py_dvt_ate/simulation/__init__.py
- Create src/py_dvt_ate/server/tcp_server.py
+- Create src/py_dvt_ate/simulation/tcp_server.py
 - Define InstrumentServer class with asyncio
 - **Commit:** "Add async TCP server foundation"
@@ -261,7 +259,7 @@ Each sprint is ~1-2 days of work, producing demonstrable progress.
 - **Commit:** "Implement TCP client handling"
 ### Task 8.3: Create server main entry point
- Create src/py_dvt_ate/server/main.py
+- Create src/py_dvt_ate/simulation/server.py
 - Wire up physics engine and instruments
 - Add CLI command to start server
 - **Commit:** "Add simulation server entry point"
@@ -278,13 +276,13 @@ Each sprint is ~1-2 days of work, producing demonstrable progress.
 **Goal:** Create client-side communication.
 ### Task 9.1: Define transport protocol
- Create src/py_dvt_ate/transport/__init__.py
+- Create src/py_dvt_ate/instruments/transport/__init__.py
- Create src/py_dvt_ate/transport/base.py
+- Create src/py_dvt_ate/instruments/transport/base.py
 - Define Transport Protocol class
 - **Commit:** "Add transport protocol definition"
 ### Task 9.2: Implement TCP transport
- Create src/py_dvt_ate/transport/tcp.py
+- Create src/py_dvt_ate/instruments/transport/tcp.py
 - Implement TCPTransport class
 - connect(), write(), read(), query() methods
 - **Commit:** "Implement TCP transport"
@@ -301,19 +299,19 @@ Each sprint is ~1-2 days of work, producing demonstrable progress.
 **Goal:** Create instrument drivers using transport.
 ### Task 10.1: Define driver base class
- Create src/py_dvt_ate/drivers/__init__.py
+- Create src/py_dvt_ate/instruments/drivers/__init__.py
- Create src/py_dvt_ate/drivers/base.py
+- Create src/py_dvt_ate/instruments/drivers/base.py
 - Define BaseDriver with transport dependency
 - **Commit:** "Add driver base class"
 ### Task 10.2: Implement thermal chamber driver
- Create src/py_dvt_ate/drivers/thermal_chamber.py
+- Create src/py_dvt_ate/instruments/drivers/chamber.py
 - Methods map to SCPI commands
 - **Commit:** "Add thermal chamber driver"
 ### Task 10.3: Implement PSU and DMM drivers
- Create src/py_dvt_ate/drivers/power_supply.py
+- Create src/py_dvt_ate/instruments/drivers/power_supply.py
- Create src/py_dvt_ate/drivers/multimeter.py
+- Create src/py_dvt_ate/instruments/drivers/multimeter.py
 - **Commit:** "Add PSU and DMM drivers"
 ### Task 10.4: Add driver tests
@@ -323,32 +321,30 @@ Each sprint is ~1-2 days of work, producing demonstrable progress.
 ---
-## Sprint 11: Hardware Abstraction Layer
+## Sprint 11: Instrument Interfaces
-**Goal:** Create HAL interfaces and implementations.
+**Goal:** Create instrument protocol interfaces and factory.
-### Task 11.1: Define HAL protocols
+### Task 11.1: Define instrument interface protocols
- Create src/py_dvt_ate/hal/__init__.py
+- Create src/py_dvt_ate/instruments/interfaces.py
- Create src/py_dvt_ate/hal/interfaces.py
+- Define IThermalChamber, IPowerSupply, IMultimeter protocols
- Define IThermalChamber, IPowerSupply, IMultimeter
+- **Commit:** "Add instrument interface protocols"
 - **Commit:** "Add HAL protocol definitions"
-### Task 11.2: Implement HAL wrappers
+### Task 11.2: Ensure drivers implement interfaces
- Create src/py_dvt_ate/hal/impl/__init__.py
+- Update drivers to satisfy Protocol interfaces
- Create HAL implementation classes
+- Add type hints for interface compliance
- Wrap drivers with HAL interface
+- **Commit:** "Implement instrument interfaces in drivers"
 - **Commit:** "Add HAL implementations"
 ### Task 11.3: Create instrument factory
- Create src/py_dvt_ate/hal/factory.py
+- Create src/py_dvt_ate/instruments/factory.py
 - InstrumentSet dataclass
 - InstrumentFactory.create() method
 - **Commit:** "Add instrument factory"
-### Task 11.4: Add HAL tests
+### Task 11.4: Add instrument interface tests
- Create tests/unit/test_hal.py
+- Create tests/unit/test_instruments.py
 - Test factory creates correct types
- **Commit:** "Add HAL unit tests"
+- **Commit:** "Add instrument interface tests"
 ---
@@ -357,13 +353,12 @@ Each sprint is ~1-2 days of work, producing demonstrable progress.
 **Goal:** YAML-based configuration.
 ### Task 12.1: Define config models
- Create src/py_dvt_ate/config/__init__.py
+- Create src/py_dvt_ate/app/config.py
- Create src/py_dvt_ate/config/models.py
+- Define Pydantic models for all config sections
 - Pydantic models for all config sections
 - **Commit:** "Add configuration Pydantic models"
 ### Task 12.2: Implement config loader
- Create src/py_dvt_ate/config/loader.py
+- Add load_config() function to src/py_dvt_ate/app/config.py
 - Load YAML, validate with Pydantic
 - Environment variable overrides
 - **Commit:** "Implement configuration loader"
@@ -410,25 +405,25 @@ Each sprint is ~1-2 days of work, producing demonstrable progress.
 **Goal:** Test execution orchestration.
 ### Task 14.1: Define test interface and models
- Create src/py_dvt_ate/executive/__init__.py
+- Create src/py_dvt_ate/framework/__init__.py
- Create src/py_dvt_ate/executive/models.py
+- Create src/py_dvt_ate/framework/context.py
 - TestStatus enum, TestContext, ITest protocol
- **Commit:** "Add test executive models"
+- **Commit:** "Add test framework models"
 ### Task 14.2: Implement test logger
- Create src/py_dvt_ate/executive/logger.py
+- Create src/py_dvt_ate/framework/logger.py
 - Log measurements and events
 - **Commit:** "Implement test logger"
 ### Task 14.3: Implement limit checker
- Create src/py_dvt_ate/executive/limits.py
+- Create src/py_dvt_ate/framework/limits.py
 - Evaluate pass/fail against limits
 - **Commit:** "Implement limit checker"
-### Task 14.4: Implement test sequencer
+### Task 14.4: Implement test runner
- Create src/py_dvt_ate/executive/sequencer.py
+- Create src/py_dvt_ate/framework/runner.py
 - Run tests, collect results
- **Commit:** "Implement test sequencer"
+- **Commit:** "Implement test runner"
 ---
@@ -443,7 +438,7 @@ Each sprint is ~1-2 days of work, producing demonstrable progress.
 - **Commit:** "Add DVT test base class"
 ### Task 15.2: Implement TempCo test
- Create src/py_dvt_ate/tests/tempco.py
+- Create src/py_dvt_ate/tests/thermal/tempco.py
 - Temperature sweep logic
 - Vout measurement at each temperature
 - TempCo calculation
@@ -517,40 +512,38 @@ Each sprint is ~1-2 days of work, producing demonstrable progress.
 ## File Dependencies Map
 ```
-physics/models.py          → (none)
+simulation/physics/models.py         → (none)
-physics/dut/base.py        → models.py
+simulation/physics/models/base.py    → models.py
-physics/dut/ldo.py         → base.py, models.py
+simulation/physics/models/ldo.py     → base.py, models.py
-physics/thermal.py         → models.py
+simulation/physics/thermal.py        → models.py
-physics/engine.py          → models.py, thermal.py, dut/base.py
+simulation/physics/engine.py         → models.py, thermal.py, models/base.py
-dashboard/app.py           → physics/engine.py (Sprint 4, direct connection)
+app/dashboard/app.py                 → simulation/physics/engine.py (Sprint 4)
-instruments/scpi_parser.py → (none)
+instruments/scpi.py                  → (none)
-instruments/base.py        → scpi_parser.py
+simulation/virtual/base.py           → instruments/scpi.py
-instruments/*_sim.py       → base.py, physics/engine.py
+simulation/virtual/*.py              → base.py, simulation/physics/engine.py
-transport/base.py          → (none)
+instruments/transport/base.py        → (none)
-transport/tcp.py           → base.py
+instruments/transport/tcp.py         → base.py
-drivers/base.py            → transport/base.py
+instruments/drivers/base.py          → instruments/transport/base.py
-drivers/*.py               → base.py
+instruments/drivers/*.py             → base.py
-hal/interfaces.py          → (none)
+instruments/interfaces.py            → (none)
-hal/impl/*.py              → interfaces.py, drivers/*.py
+instruments/factory.py               → interfaces.py, drivers/*.py
 hal/factory.py             → interfaces.py, impl/*.py
-config/models.py           → (none)
+app/config.py                        → (none)
 config/loader.py           → models.py
 data/models.py                       → (none)
 data/repository.py                   → models.py
-executive/models.py        → hal/interfaces.py
+framework/context.py                 → instruments/interfaces.py
-executive/*.py             → models.py, data/repository.py
+framework/*.py                       → context.py, data/repository.py
-tests/*.py                 → executive/models.py, hal/interfaces.py
+tests/*.py                           → framework/context.py, instruments/interfaces.py
-dashboard/app.py           → hal/factory.py (Sprint 17, upgraded)
+app/dashboard/app.py                 → instruments/factory.py (Sprint 17, upgraded)
 ```
 ---
@@ -578,7 +571,7 @@ MAJOR.MINOR.PATCH[-PRERELEASE]
 | 3 | `v0.1.0-alpha.1` | Physics engine working | Pre-release |
 | 4 | `v0.1.0-alpha.2` | Visual demo (dashboard) | Pre-release |
 | 8 | `v0.1.0-alpha.3` | Network ready (TCP server) | Pre-release |
-| 11 | `v0.1.0-beta.1` | HAL complete | Pre-release |
+| 11 | `v0.1.0-beta.1` | Interfaces complete | Pre-release |
 | 15 | `v0.1.0-beta.2` | First DVT test runs | Pre-release |
 | 17 | `v0.1.0` | **MVP Complete** | Release |
@@ -644,7 +637,7 @@ Maintain `CHANGELOG.md` following [Keep a Changelog](https://keepachangelog.com/
 | 4 | `v0.1.0-alpha.2` | **Visual Demo!** | Interactive Streamlit showing physics |
 | 7 | - | Instruments Done | SCPI simulators respond to commands |
 | 8 | `v0.1.0-alpha.3` | Network Ready | TCP server accepts connections |
-| 11 | `v0.1.0-beta.1` | HAL Complete | Abstraction layer swappable |
+| 11 | `v0.1.0-beta.1` | Interfaces Complete | Instrument layer swappable |
 | 15 | `v0.1.0-beta.2` | First Test | TempCo characterisation runs |
 | 17 | `v0.1.0` | **MVP Complete** | Full end-to-end workflow |
--- a/pyproject.toml
+++ b/pyproject.toml
@@ -37,12 +37,13 @@ dev = [
    "pytest-asyncio>=0.21",
    "ruff>=0.1",
    "mypy>=1.0",
    "types-PyYAML>=6.0",
 ]
 [project.scripts]
-py-dvt-ate = "py_dvt_ate.cli.main:app"
+py-dvt-ate = "py_dvt_ate.app.cli:app"
-py-dvt-ate-server = "py_dvt_ate.server.main:main"
+py-dvt-ate-server = "py_dvt_ate.simulation.server:main"
-py-dvt-ate-dashboard = "py_dvt_ate.dashboard.app:main"
+py-dvt-ate-dashboard = "py_dvt_ate.app.dashboard.app:main"
 [build-system]
 requires = ["hatchling"]
@@ -86,5 +87,8 @@ ignore_missing_imports = true
 [tool.pytest.ini_options]
 testpaths = ["tests"]
 asyncio_mode = "auto"
 addopts = "-v --tb=short"
 [tool.pytest-asyncio]
 mode = "auto"
 default_fixture_loop_scope = "function"
--- a/src/py_dvt_ate/init.py
+++ b/src/py_dvt_ate/init.py
@@ -1,3 +1,3 @@
 """py_dvt_ate: Coupled Physics DVT Simulation Platform."""
-__version__ = "0.0.1"
+__version__ = "0.1.0-beta.2"
--- a/src/py_dvt_ate/app/init.py
+++ b/src/py_dvt_ate/app/init.py
@@ -0,0 +1,5 @@
 """Application entry points.
 Contains CLI, dashboard, and configuration loading for the
 py_dvt_ate application.
 """
--- a/src/py_dvt_ate/app/cli.py
+++ b/src/py_dvt_ate/app/cli.py
@@ -0,0 +1,87 @@
 """Command-line interface for py_dvt_ate."""
 from typing import Annotated
 import typer
 from py_dvt_ate import __version__
 app = typer.Typer(
    name="py-dvt-ate",
    help="Coupled Physics DVT Simulation Platform",
    add_completion=False,
 )
 def version_callback(value: bool) -> None:
    """Print version and exit."""
    if value:
        typer.echo(f"py-dvt-ate version {__version__}")
        raise typer.Exit()
@app.callback()
 def main(
    version: Annotated[
        bool | None,
        typer.Option(
            "--version",
            "-v",
            help="Show version and exit.",
            callback=version_callback,
            is_eager=True,
        ),
    ] = None,
 ) -> None:
    """py-dvt-ate: Coupled Physics DVT Simulation Platform."""
@app.command()
 def serve(
    host: Annotated[
        str,
        typer.Option("--host", "-h", help="Host address to bind to."),
    ] = "127.0.0.1",
    chamber_port: Annotated[
        int,
        typer.Option("--chamber-port", help="Port for thermal chamber instrument."),
    ] = 5000,
    psu_port: Annotated[
        int,
        typer.Option("--psu-port", help="Port for power supply instrument."),
    ] = 5001,
    dmm_port: Annotated[
        int,
        typer.Option("--dmm-port", help="Port for multimeter instrument."),
    ] = 5002,
    physics_rate: Annotated[
        float,
        typer.Option("--physics-rate", help="Physics engine update rate in Hz."),
    ] = 100.0,
 ) -> None:
    """Start the simulation server with virtual instruments.
    Runs a TCP server hosting virtual SCPI instruments connected to a
    shared physics engine. Each instrument listens on its own port.
    """
    from py_dvt_ate.simulation.server import main as run_server
    typer.echo(f"Starting simulation server on {host}...")
    typer.echo(f"  Thermal chamber: port {chamber_port}")
    typer.echo(f"  Power supply:    port {psu_port}")
    typer.echo(f"  Multimeter:      port {dmm_port}")
    typer.echo(f"  Physics rate:    {physics_rate} Hz")
    typer.echo("")
    typer.echo("Press Ctrl+C to stop.")
    run_server(
        host=host,
        chamber_port=chamber_port,
        psu_port=psu_port,
        dmm_port=dmm_port,
        physics_rate=physics_rate,
    )
 if __name__ == "__main__":
    app()
--- a/src/py_dvt_ate/app/config.py
+++ b/src/py_dvt_ate/app/config.py
@@ -0,0 +1,200 @@
 """Configuration models for py_dvt_ate.
 This module defines Pydantic models for all configuration sections.
 Configuration can be loaded from YAML files and validated at runtime.
 """
 import os
 from pathlib import Path
 from typing import Any, Literal
 import yaml
 from pydantic import BaseModel, Field
 class SimulatorConfig(BaseModel):
    """Configuration for simulator instrument backend."""
    host: str = "localhost"
    thermal_chamber_port: int = 5001
    power_supply_port: int = 5002
    multimeter_port: int = 5003
 class PyVISAConfig(BaseModel):
    """Configuration for PyVISA instrument backend."""
    thermal_chamber: str | None = None
    power_supply: str | None = None
    multimeter: str | None = None
 class InstrumentsConfig(BaseModel):
    """Instrument backend configuration."""
    backend: Literal["simulator", "pyvisa"] = "simulator"
    simulator: SimulatorConfig = Field(default_factory=SimulatorConfig)
    pyvisa: PyVISAConfig = Field(default_factory=PyVISAConfig)
 class ThermalConfig(BaseModel):
    """Thermal physics parameters."""
    chamber_time_constant_s: float = 30.0
    case_time_constant_s: float = 5.0
    theta_jc: float = 15.0  # °C/W (junction to case)
    theta_ca: float = 5.0  # °C/W (case to ambient)
 class ChamberConfig(BaseModel):
    """Thermal chamber behaviour parameters."""
    ramp_rate_c_per_min: float = 10.0
    stability_window_c: float = 0.5
    stability_time_s: float = 30.0
 class PhysicsConfig(BaseModel):
    """Physics simulation parameters."""
    update_rate_hz: float = 100.0
    thermal: ThermalConfig = Field(default_factory=ThermalConfig)
    chamber: ChamberConfig = Field(default_factory=ChamberConfig)
 class DUTParameters(BaseModel):
    """DUT model parameters."""
    nominal_output_voltage: float = 3.3
    tempco_ppm_per_c: float = 50.0
    quiescent_current_ua: float = 50.0
    quiescent_current_tempco: float = 0.003
    dropout_voltage: float = 0.3
 class DUTConfig(BaseModel):
    """DUT model configuration."""
    model: str = "ldo"
    parameters: DUTParameters = Field(default_factory=DUTParameters)
 class DataConfig(BaseModel):
    """Data storage paths."""
    database_path: str = "./data/py_dvt_ate.db"
    measurements_dir: str = "./data/measurements"
    reports_dir: str = "./data/reports"
 class LoggingConfig(BaseModel):
    """Logging configuration."""
    level: str = "INFO"
    file: str = "./data/logs/py_dvt_ate.log"
    format: str = "%(asctime)s - %(name)s - %(levelname)s - %(message)s"
 class DashboardConfig(BaseModel):
    """Dashboard (Streamlit) configuration."""
    enabled: bool = True
    port: int = 8501
 class APIConfig(BaseModel):
    """API server configuration (Phase 2)."""
    enabled: bool = False
    host: str = "0.0.0.0"
    port: int = 8000
 class AppConfig(BaseModel):
    """Root configuration model."""
    instruments: InstrumentsConfig = Field(default_factory=InstrumentsConfig)
    physics: PhysicsConfig = Field(default_factory=PhysicsConfig)
    dut: DUTConfig = Field(default_factory=DUTConfig)
    data: DataConfig = Field(default_factory=DataConfig)
    logging: LoggingConfig = Field(default_factory=LoggingConfig)
    dashboard: DashboardConfig = Field(default_factory=DashboardConfig)
    api: APIConfig = Field(default_factory=APIConfig)
 def _apply_env_overrides(config_dict: dict[str, Any]) -> None:
    """Apply environment variable overrides to config dictionary.
    Environment variables follow the pattern: PYDVTATE__{SECTION}__{KEY}
    For nested keys, use double underscores: PYDVTATE__{SECTION}__{SUBSECTION}__{KEY}
    Examples:
        PYDVTATE__INSTRUMENTS__BACKEND=pyvisa
        PYDVTATE__PHYSICS__UPDATE_RATE_HZ=50.0
        PYDVTATE__SIMULATOR__HOST=192.168.1.100
    """
    prefix = "PYDVTATE__"
    for env_key, env_value in os.environ.items():
        if not env_key.startswith(prefix):
            continue
        # Remove prefix and split into parts
        key_parts = env_key[len(prefix) :].lower().split("__")
        # Navigate/create nested structure
        current = config_dict
        for part in key_parts[:-1]:
            if part not in current:
                current[part] = {}
            current = current[part]
        # Set the final value
        final_key = key_parts[-1]
        # Try to parse as YAML to handle types (int, float, bool, etc.)
        try:
            current[final_key] = yaml.safe_load(env_value)
        except yaml.YAMLError:
            # If parsing fails, use as string
            current[final_key] = env_value
 def load_config(config_path: str | Path | None = None) -> AppConfig:
    """Load configuration from YAML file with environment variable overrides.
    Args:
        config_path: Path to YAML configuration file. If None, uses defaults only.
    Returns:
        Validated AppConfig instance.
    Raises:
        FileNotFoundError: If config_path is provided but does not exist.
        yaml.YAMLError: If YAML file is malformed.
        pydantic.ValidationError: If configuration is invalid.
    Environment Variables:
        Configuration can be overridden using environment variables with the
        pattern PYDVTATE__{SECTION}__{KEY}. For example:
            PYDVTATE__INSTRUMENTS__BACKEND=pyvisa
            PYDVTATE__PHYSICS__UPDATE_RATE_HZ=50.0
    """
    # Start with empty dict (will use Pydantic defaults)
    config_dict: dict[str, Any] = {}
    # Load from YAML file if provided
    if config_path is not None:
        path = Path(config_path)
        if not path.exists():
            raise FileNotFoundError(f"Configuration file not found: {config_path}")
        with path.open("r") as f:
            loaded = yaml.safe_load(f)
            if loaded is not None:
                config_dict = loaded
    # Apply environment variable overrides
    _apply_env_overrides(config_dict)
    # Validate and return
    return AppConfig(**config_dict)
--- a/src/py_dvt_ate/app/dashboard/init.py
+++ b/src/py_dvt_ate/app/dashboard/init.py
@@ -0,0 +1,9 @@
 """Streamlit dashboard for real-time monitoring.
 Provides visualisation of instrument status, test progress,
 and historical results.
 """
 from py_dvt_ate.app.dashboard.app import main
 __all__ = ["main"]
--- a/src/py_dvt_ate/app/dashboard/app.py
+++ b/src/py_dvt_ate/app/dashboard/app.py
@@ -0,0 +1,320 @@
 """Streamlit dashboard application for physics simulation visualisation.
 This module provides an interactive dashboard for visualising the physics
 engine directly, demonstrating thermal-electrical coupling in real-time.
 """
 import time
 from collections import deque
 from dataclasses import dataclass, field
 import streamlit as st
 from py_dvt_ate.simulation.physics.engine import PhysicsEngine
 # History buffer size for charts
 HISTORY_SIZE = 500
@dataclass
 class SimulationHistory:
    """Stores time series data for visualisation."""
    time: deque[float] = field(default_factory=lambda: deque(maxlen=HISTORY_SIZE))
    chamber_temp: deque[float] = field(
        default_factory=lambda: deque(maxlen=HISTORY_SIZE)
    )
    case_temp: deque[float] = field(default_factory=lambda: deque(maxlen=HISTORY_SIZE))
    junction_temp: deque[float] = field(
        default_factory=lambda: deque(maxlen=HISTORY_SIZE)
    )
    output_voltage: deque[float] = field(
        default_factory=lambda: deque(maxlen=HISTORY_SIZE)
    )
    power_dissipation: deque[float] = field(
        default_factory=lambda: deque(maxlen=HISTORY_SIZE)
    )
 def init_session_state() -> None:
    """Initialise Streamlit session state."""
    if "engine" not in st.session_state:
        st.session_state.engine = PhysicsEngine(update_rate_hz=100.0)
    if "history" not in st.session_state:
        st.session_state.history = SimulationHistory()
    if "running" not in st.session_state:
        st.session_state.running = False
    if "last_update" not in st.session_state:
        st.session_state.last_update = time.time()
    # Note: time_multiplier, temp_setpoint, input_voltage, output_enabled,
    # load_current are managed by their respective widgets via keys
 def step_simulation() -> None:
    """Advance the simulation based on elapsed real time and multiplier."""
    engine: PhysicsEngine = st.session_state.engine
    history: SimulationHistory = st.session_state.history
    multiplier: float = st.session_state.get("time_multiplier", 10)
    # Calculate how much simulation time to advance
    current_time = time.time()
    elapsed_real = current_time - st.session_state.last_update
    st.session_state.last_update = current_time
    # Simulation time to advance (capped to prevent huge jumps)
    sim_time_to_advance = min(elapsed_real * multiplier, 2.0)
    # Calculate number of steps needed
    steps = int(sim_time_to_advance / engine.dt)
    steps = max(1, min(steps, 1000))  # Clamp between 1 and 1000 steps
    for _ in range(steps):
        engine.step()
    # Record current state in history
    thermal = engine.get_thermal_state()
    electrical = engine.get_electrical_state()
    history.time.append(thermal.timestamp)
    history.chamber_temp.append(thermal.chamber_temperature)
    history.case_temp.append(thermal.case_temperature)
    history.junction_temp.append(thermal.junction_temperature)
    history.output_voltage.append(electrical.output_voltage)
    history.power_dissipation.append(electrical.power_dissipation)
 def sync_engine_from_session_state() -> None:
    """Sync engine parameters from session state (called by fragment)."""
    engine: PhysicsEngine = st.session_state.engine
    engine.set_chamber_setpoint(st.session_state.get("temp_setpoint", 25.0))
    engine.set_input_voltage(st.session_state.get("input_voltage", 5.0))
    engine.set_output_enabled(st.session_state.get("output_enabled", False))
    engine.set_load_current(st.session_state.get("load_current", 100.0) / 1000.0)
 def display_controls() -> None:
    """Display simulation control panel in sidebar."""
    st.sidebar.header("Simulation Controls")
    # Start/Stop button
    if st.session_state.running:
        if st.sidebar.button(
            "Stop Simulation", type="primary", use_container_width=True
        ):
            st.session_state.running = False
    else:
        if st.sidebar.button(
            "Start Simulation", type="primary", use_container_width=True
        ):
            st.session_state.running = True
            st.session_state.last_update = time.time()
    # Reset button
    if st.sidebar.button("Reset", use_container_width=True):
        st.session_state.engine = PhysicsEngine(update_rate_hz=100.0)
        st.session_state.history = SimulationHistory()
        st.session_state.running = False
        st.session_state.last_update = time.time()
    st.sidebar.divider()
    # Time multiplier
    st.sidebar.subheader("Simulation Speed")
    st.sidebar.select_slider(
        "Time Multiplier",
        options=[1, 2, 5, 10, 20, 50, 100],
        value=10,
        format_func=lambda x: f"{x}x",
        key="time_multiplier",
    )
    st.sidebar.caption(
        f"1 real second = {st.session_state.get('time_multiplier', 10)} simulation seconds"
    )
    st.sidebar.divider()
    # Temperature setpoint
    st.sidebar.subheader("Thermal Chamber")
    st.sidebar.slider(
        "Temperature Setpoint (C)",
        min_value=-40.0,
        max_value=125.0,
        value=25.0,
        step=5.0,
        key="temp_setpoint",
    )
    st.sidebar.divider()
    # Power supply controls
    st.sidebar.subheader("Power Supply")
    st.sidebar.slider(
        "Input Voltage (V)",
        min_value=0.0,
        max_value=12.0,
        value=5.0,
        step=0.1,
        key="input_voltage",
    )
    st.sidebar.toggle(
        "Output Enabled",
        value=False,
        key="output_enabled",
    )
    st.sidebar.divider()
    # Load controls
    st.sidebar.subheader("Electronic Load")
    st.sidebar.slider(
        "Load Current (mA)",
        min_value=0.0,
        max_value=500.0,
        value=100.0,
        step=10.0,
        key="load_current",
    )
@st.fragment(run_every=0.1)
 def simulation_display() -> None:
    """Fragment that displays and updates simulation state."""
    engine: PhysicsEngine = st.session_state.engine
    history: SimulationHistory = st.session_state.history
    # Sync engine parameters from UI controls
    sync_engine_from_session_state()
    # Step simulation if running
    if st.session_state.running:
        step_simulation()
    # Get current state
    thermal = engine.get_thermal_state()
    electrical = engine.get_electrical_state()
    # Current state metrics
    st.subheader("Current State")
    col1, col2, col3, col4 = st.columns(4)
    with col1:
        st.metric("Chamber Temp", f"{thermal.chamber_temperature:.2f} C")
    with col2:
        st.metric("Case Temp", f"{thermal.case_temperature:.2f} C")
    with col3:
        st.metric("Junction Temp", f"{thermal.junction_temperature:.2f} C")
    with col4:
        st.metric("Output Voltage", f"{electrical.output_voltage:.4f} V")
    col5, col6, col7, col8 = st.columns(4)
    with col5:
        st.metric("Input Voltage", f"{electrical.input_voltage:.2f} V")
    with col6:
        st.metric("Load Current", f"{electrical.load_current * 1000:.1f} mA")
    with col7:
        st.metric("Power Diss.", f"{electrical.power_dissipation * 1000:.2f} mW")
    with col8:
        status = "Running" if st.session_state.running else "Stopped"
        st.metric(
            "Sim Time",
            f"{engine.simulation_time:.1f} s",
            delta=f"{status} @ {st.session_state.get('time_multiplier', 10):.0f}x",
        )
    # Temperature chart
    st.subheader("Temperature History")
    if len(history.time) < 2:
        st.info("Start the simulation to see temperature data")
    else:
        chart_data = {
            "Time (s)": list(history.time),
            "Chamber": list(history.chamber_temp),
            "Case": list(history.case_temp),
            "Junction": list(history.junction_temp),
        }
        st.line_chart(
            chart_data,
            x="Time (s)",
            y=["Chamber", "Case", "Junction"],
            color=["#1f77b4", "#ff7f0e", "#d62728"],
        )
    # Self-heating demonstration
    st.subheader("Self-Heating Demonstration")
    delta_t_jc = thermal.junction_temperature - thermal.case_temperature
    delta_t_ca = thermal.case_temperature - thermal.chamber_temperature
    col1, col2 = st.columns(2)
    with col1:
        st.markdown("#### Self-Heating Analysis")
        st.markdown(
            f"""
 | Parameter | Value |
 |-----------|-------|
 | Junction-Case Rise (dT_jc) | **{delta_t_jc:.2f} C** |
 | Case-Ambient Rise (dT_ca) | **{delta_t_ca:.2f} C** |
 | Power Dissipation | {electrical.power_dissipation * 1000:.1f} mW |
 | theta_jc (junction-case) | 15 C/W |
 | theta_ca (case-ambient) | 5 C/W |
 """
        )
        st.markdown(
            """
 **Thermal Coupling:** The junction temperature rises above the case
 temperature due to power dissipation. This is governed by:
 `T_junction = T_case + P_diss x theta_jc`
 Try increasing the load current or input voltage to see
 self-heating effects!
 """
        )
    with col2:
        st.markdown("#### Power Dissipation")
        if len(history.time) < 2:
            st.info("Start the simulation to see power data")
        else:
            power_data = {
                "Time (s)": list(history.time),
                "Power (mW)": [p * 1000 for p in history.power_dissipation],
            }
            st.line_chart(
                power_data,
                x="Time (s)",
                y="Power (mW)",
                color="#2ca02c",
            )
 def main() -> None:
    """Main entry point for the Streamlit dashboard."""
    st.set_page_config(
        page_title="py-dvt-ate Virtual Lab Bench",
        page_icon="🔬",
        layout="wide",
    )
    st.title("py-dvt-ate Virtual Lab Bench")
    st.markdown(
        """
        Interactive physics simulation demonstrating coupled thermal-electrical
        behaviour of an LDO voltage regulator.
        """
    )
    init_session_state()
    # Sidebar controls (static - doesn't need fragment)
    display_controls()
    # Dynamic simulation display (uses fragment for smooth updates)
    simulation_display()
 if __name__ == "__main__":
    main()
--- a/src/py_dvt_ate/cli/init.py
+++ b/src/py_dvt_ate/cli/init.py
@@ -1 +0,0 @@
 """Command-line interface."""
--- a/src/py_dvt_ate/cli/main.py
+++ b/src/py_dvt_ate/cli/main.py
@@ -1,40 +0,0 @@
 """Command-line interface for py_dvt_ate."""
 from typing import Annotated, Optional
 import typer
 from py_dvt_ate import __version__
 app = typer.Typer(
    name="py-dvt-ate",
    help="Coupled Physics DVT Simulation Platform",
    add_completion=False,
 )
 def version_callback(value: bool) -> None:
    """Print version and exit."""
    if value:
        typer.echo(f"py-dvt-ate version {__version__}")
        raise typer.Exit()
@app.callback()
 def main(
    version: Annotated[
        Optional[bool],
        typer.Option(
            "--version",
            "-v",
            help="Show version and exit.",
            callback=version_callback,
            is_eager=True,
        ),
    ] = None,
 ) -> None:
    """py-dvt-ate: Coupled Physics DVT Simulation Platform."""
 if __name__ == "__main__":
    app()
--- a/src/py_dvt_ate/config/init.py
+++ b/src/py_dvt_ate/config/init.py
@@ -1 +0,0 @@
 """Configuration handling."""
--- a/src/py_dvt_ate/dashboard/init.py
+++ b/src/py_dvt_ate/dashboard/init.py
@@ -1 +0,0 @@
 """Streamlit dashboard."""
--- a/src/py_dvt_ate/data/init.py
+++ b/src/py_dvt_ate/data/init.py
@@ -0,0 +1,14 @@
 """Data persistence layer.
 Provides storage for test runs, results, and measurements using
 SQLite for metadata and Parquet for time-series data.
 """
 from py_dvt_ate.data.models import Measurement, TestResult, TestRun, TestStatus
 __all__ = [
    "Measurement",
    "TestResult",
    "TestRun",
    "TestStatus",
 ]
--- a/src/py_dvt_ate/data/models.py
+++ b/src/py_dvt_ate/data/models.py
@@ -0,0 +1,83 @@
 """Data models for test persistence.
 This module defines dataclasses representing test runs, results, and measurements.
 These models map to SQLite tables (for metadata) and Parquet files (for time-series).
 """
 from dataclasses import dataclass, field
 from datetime import datetime
 from enum import Enum
 class TestStatus(Enum):
    """Test run status."""
    PENDING = "pending"
    RUNNING = "running"
    PASSED = "passed"
    FAILED = "failed"
    ERROR = "error"
    SKIPPED = "skipped"
@dataclass
 class TestRun:
    """Test run metadata.
    Maps to the test_runs SQLite table.
    """
    id: str  # UUID
    test_name: str
    started_at: datetime
    status: TestStatus
    config_json: str  # JSON string of test configuration
    description: str | None = None
    completed_at: datetime | None = None
    operator: str | None = None
    notes: str | None = None
    created_at: datetime = field(default_factory=datetime.now)
@dataclass(frozen=True)
 class TestResult:
    """Immutable test result with limits.
    Maps to the test_results SQLite table.
    Represents a single scalar measurement with pass/fail limits.
    """
    id: str  # UUID
    test_run_id: str  # Foreign key to test_runs.id
    parameter: str
    value: float
    unit: str
    measured_at: datetime
    lower_limit: float | None = None
    upper_limit: float | None = None
    @property
    def passed(self) -> bool | None:
        """Evaluate pass/fail. None if no limits defined."""
        if self.lower_limit is None and self.upper_limit is None:
            return None
        lower_ok = self.lower_limit is None or self.value >= self.lower_limit
        upper_ok = self.upper_limit is None or self.value <= self.upper_limit
        return lower_ok and upper_ok
@dataclass(frozen=True)
 class Measurement:
    """Immutable measurement record for time-series data.
    Maps to Parquet files for efficient storage and analysis.
    Includes measurement conditions (temperature, voltage, current) at time of measurement.
    """
    timestamp: float  # Seconds since epoch (high precision)
    parameter: str
    value: float
    unit: str
    temperature: float = 0.0  # Chamber temperature at measurement
    input_voltage: float = 0.0  # DUT input voltage at measurement
    load_current: float = 0.0  # DUT load current at measurement
--- a/src/py_dvt_ate/data/repository.py
+++ b/src/py_dvt_ate/data/repository.py
@@ -0,0 +1,359 @@
 """Data repository implementation using SQLite and Parquet.
 This module provides SQLite-based storage for test run metadata and results.
 Time-series measurements are stored separately in Parquet files.
 """
 import json
 import sqlite3
 from abc import ABC, abstractmethod
 from datetime import datetime
 from pathlib import Path
 from typing import Any
 from uuid import UUID, uuid4
 import pandas as pd
 from py_dvt_ate.data.models import Measurement, TestResult, TestRun, TestStatus
 class ITestRepository(ABC):
    """Repository interface for test data."""
    @abstractmethod
    def create_run(
        self,
        test_name: str,
        config: dict[str, Any],
        operator: str | None = None,
        description: str | None = None,
    ) -> UUID:
        """Create a new test run and return its ID."""
    @abstractmethod
    def update_run_status(self, run_id: UUID, status: TestStatus) -> None:
        """Update the status of a test run."""
    @abstractmethod
    def complete_run(self, run_id: UUID, status: TestStatus) -> None:
        """Mark a test run as complete with final status."""
    @abstractmethod
    def save_result(
        self,
        run_id: UUID,
        parameter: str,
        value: float,
        unit: str,
        lower_limit: float | None = None,
        upper_limit: float | None = None,
    ) -> None:
        """Save a scalar test result."""
    @abstractmethod
    def save_measurements(
        self,
        run_id: UUID,
        measurements: list[Measurement],
    ) -> None:
        """Save time-series measurements (implemented in Parquet extension)."""
    @abstractmethod
    def get_run(self, run_id: UUID) -> TestRun:
        """Retrieve test run metadata by ID."""
    @abstractmethod
    def get_results(self, run_id: UUID) -> list[TestResult]:
        """Retrieve all test results for a run."""
    @abstractmethod
    def get_measurements_dataframe(self, run_id: UUID) -> pd.DataFrame | None:
        """Retrieve measurements as pandas DataFrame."""
 class SQLiteRepository(ITestRepository):
    """SQLite-based repository for test data.
    Stores test run metadata and scalar results in SQLite.
    Time-series measurements are stored in Parquet files.
    """
    def __init__(self, db_path: str | Path, measurements_dir: str | Path | None = None):
        """Initialise repository with database and measurements paths.
        Args:
            db_path: Path to SQLite database file
            measurements_dir: Directory for Parquet measurement files
                            (defaults to db_path parent / "measurements")
        """
        self.db_path = Path(db_path)
        self.db_path.parent.mkdir(parents=True, exist_ok=True)
        if measurements_dir is None:
            self.measurements_dir = self.db_path.parent / "measurements"
        else:
            self.measurements_dir = Path(measurements_dir)
        self.measurements_dir.mkdir(parents=True, exist_ok=True)
        self._init_database()
    def _init_database(self) -> None:
        """Create database tables if they don't exist."""
        with sqlite3.connect(self.db_path) as conn:
            conn.execute(
                """
                CREATE TABLE IF NOT EXISTS test_runs (
                    id TEXT PRIMARY KEY,
                    test_name TEXT NOT NULL,
                    description TEXT,
                    started_at TEXT NOT NULL,
                    completed_at TEXT,
                    status TEXT NOT NULL DEFAULT 'pending',
                    config_json TEXT NOT NULL,
                    operator TEXT,
                    notes TEXT,
                    created_at TEXT NOT NULL DEFAULT (datetime('now'))
                )
                """
            )
            conn.execute(
                """
                CREATE TABLE IF NOT EXISTS test_results (
                    id TEXT PRIMARY KEY,
                    test_run_id TEXT NOT NULL,
                    parameter TEXT NOT NULL,
                    value REAL NOT NULL,
                    unit TEXT,
                    lower_limit REAL,
                    upper_limit REAL,
                    passed INTEGER NOT NULL,
                    measured_at TEXT NOT NULL,
                    FOREIGN KEY (test_run_id) REFERENCES test_runs(id)
                )
                """
            )
            conn.execute(
                "CREATE INDEX IF NOT EXISTS idx_test_runs_status ON test_runs(status)"
            )
            conn.execute(
                "CREATE INDEX IF NOT EXISTS idx_test_runs_name ON test_runs(test_name)"
            )
            conn.execute(
                "CREATE INDEX IF NOT EXISTS idx_test_results_run ON test_results(test_run_id)"
            )
            conn.execute(
                "CREATE INDEX IF NOT EXISTS idx_test_results_param ON test_results(parameter)"
            )
            conn.commit()
    def create_run(
        self,
        test_name: str,
        config: dict[str, Any],
        operator: str | None = None,
        description: str | None = None,
    ) -> UUID:
        """Create a new test run and return its ID."""
        run_id = uuid4()
        started_at = datetime.now()
        config_json = json.dumps(config)
        with sqlite3.connect(self.db_path) as conn:
            conn.execute(
                """
                INSERT INTO test_runs (
                    id, test_name, description, started_at, status,
                    config_json, operator, created_at
                )
                VALUES (?, ?, ?, ?, ?, ?, ?, ?)
                """,
                (
                    str(run_id),
                    test_name,
                    description,
                    started_at.isoformat(),
                    TestStatus.PENDING.value,
                    config_json,
                    operator,
                    datetime.now().isoformat(),
                ),
            )
            conn.commit()
        return run_id
    def update_run_status(self, run_id: UUID, status: TestStatus) -> None:
        """Update the status of a test run."""
        with sqlite3.connect(self.db_path) as conn:
            conn.execute(
                "UPDATE test_runs SET status = ? WHERE id = ?",
                (status.value, str(run_id)),
            )
            conn.commit()
    def complete_run(self, run_id: UUID, status: TestStatus) -> None:
        """Mark a test run as complete with final status."""
        completed_at = datetime.now()
        with sqlite3.connect(self.db_path) as conn:
            conn.execute(
                """
                UPDATE test_runs
                SET status = ?, completed_at = ?
                WHERE id = ?
                """,
                (status.value, completed_at.isoformat(), str(run_id)),
            )
            conn.commit()
    def save_result(
        self,
        run_id: UUID,
        parameter: str,
        value: float,
        unit: str,
        lower_limit: float | None = None,
        upper_limit: float | None = None,
    ) -> None:
        """Save a scalar test result."""
        result_id = uuid4()
        measured_at = datetime.now()
        # Calculate pass/fail
        passed = 1  # Default to pass if no limits
        if lower_limit is not None or upper_limit is not None:
            lower_ok = lower_limit is None or value >= lower_limit
            upper_ok = upper_limit is None or value <= upper_limit
            passed = 1 if (lower_ok and upper_ok) else 0
        with sqlite3.connect(self.db_path) as conn:
            conn.execute(
                """
                INSERT INTO test_results (
                    id, test_run_id, parameter, value, unit,
                    lower_limit, upper_limit, passed, measured_at
                )
                VALUES (?, ?, ?, ?, ?, ?, ?, ?, ?)
                """,
                (
                    str(result_id),
                    str(run_id),
                    parameter,
                    value,
                    unit,
                    lower_limit,
                    upper_limit,
                    passed,
                    measured_at.isoformat(),
                ),
            )
            conn.commit()
    def save_measurements(
        self,
        run_id: UUID,
        measurements: list[Measurement],
    ) -> None:
        """Save time-series measurements to Parquet file.
        Measurements are stored in Parquet format for efficient time-series storage.
        File path: {measurements_dir}/run_{run_id}/measurements.parquet
        """
        if not measurements:
            return
        # Create run-specific directory
        run_dir = self.measurements_dir / f"run_{run_id}"
        run_dir.mkdir(parents=True, exist_ok=True)
        # Convert measurements to DataFrame
        data = {
            "timestamp": [m.timestamp for m in measurements],
            "parameter": [m.parameter for m in measurements],
            "value": [m.value for m in measurements],
            "unit": [m.unit for m in measurements],
            "temperature": [m.temperature for m in measurements],
            "input_voltage": [m.input_voltage for m in measurements],
            "load_current": [m.load_current for m in measurements],
        }
        df = pd.DataFrame(data)
        # Save to Parquet (append mode if file exists)
        parquet_path = run_dir / "measurements.parquet"
        if parquet_path.exists():
            # Read existing data and append
            existing_df = pd.read_parquet(parquet_path)
            df = pd.concat([existing_df, df], ignore_index=True)
        df.to_parquet(parquet_path, index=False, engine="pyarrow")
    def get_run(self, run_id: UUID) -> TestRun:
        """Retrieve test run metadata by ID."""
        with sqlite3.connect(self.db_path) as conn:
            conn.row_factory = sqlite3.Row
            cursor = conn.execute(
                "SELECT * FROM test_runs WHERE id = ?",
                (str(run_id),),
            )
            row = cursor.fetchone()
            if row is None:
                msg = f"Test run {run_id} not found"
                raise ValueError(msg)
            return TestRun(
                id=row["id"],
                test_name=row["test_name"],
                description=row["description"],
                started_at=datetime.fromisoformat(row["started_at"]),
                completed_at=(
                    datetime.fromisoformat(row["completed_at"])
                    if row["completed_at"]
                    else None
                ),
                status=TestStatus(row["status"]),
                config_json=row["config_json"],
                operator=row["operator"],
                notes=row["notes"],
                created_at=datetime.fromisoformat(row["created_at"]),
            )
    def get_results(self, run_id: UUID) -> list[TestResult]:
        """Retrieve all test results for a run."""
        with sqlite3.connect(self.db_path) as conn:
            conn.row_factory = sqlite3.Row
            cursor = conn.execute(
                "SELECT * FROM test_results WHERE test_run_id = ?",
                (str(run_id),),
            )
            rows = cursor.fetchall()
            return [
                TestResult(
                    id=row["id"],
                    test_run_id=row["test_run_id"],
                    parameter=row["parameter"],
                    value=row["value"],
                    unit=row["unit"],
                    lower_limit=row["lower_limit"],
                    upper_limit=row["upper_limit"],
                    measured_at=datetime.fromisoformat(row["measured_at"]),
                )
                for row in rows
            ]
    def get_measurements_dataframe(self, run_id: UUID) -> pd.DataFrame | None:
        """Retrieve measurements as pandas DataFrame from Parquet file.
        Args:
            run_id: Test run ID
        Returns:
            DataFrame with measurement data, or None if no measurements exist
        """
        parquet_path = self.measurements_dir / f"run_{run_id}" / "measurements.parquet"
        if not parquet_path.exists():
            return None
        return pd.read_parquet(parquet_path)
--- a/src/py_dvt_ate/drivers/init.py
+++ b/src/py_dvt_ate/drivers/init.py
@@ -1 +0,0 @@
 """Instrument SCPI drivers."""
--- a/src/py_dvt_ate/executive/init.py
+++ b/src/py_dvt_ate/executive/init.py
@@ -1 +0,0 @@
 """Test execution framework."""
--- a/src/py_dvt_ate/framework/init.py
+++ b/src/py_dvt_ate/framework/init.py
@@ -0,0 +1,22 @@
 """Test execution framework.
 Provides test sequencing, measurement logging, limit checking,
 and runtime context management for DVT characterisation tests.
 """
 from py_dvt_ate.framework.context import ITest, TestContext
 from py_dvt_ate.framework.limits import Limit, LimitSet, check_value, evaluate_results
 from py_dvt_ate.framework.logger import ITestLogger, TestLogger
 from py_dvt_ate.framework.runner import TestRunner
 __all__ = [
    "ITest",
    "ITestLogger",
    "Limit",
    "LimitSet",
    "TestContext",
    "TestLogger",
    "TestRunner",
    "check_value",
    "evaluate_results",
 ]
--- a/src/py_dvt_ate/framework/context.py
+++ b/src/py_dvt_ate/framework/context.py
@@ -0,0 +1,111 @@
 """Test framework context and interface definitions.
 This module defines the core abstractions for the test executive framework:
 - TestContext: Runtime context passed to tests during execution
 - ITest: Abstract base class that all DVT tests must implement
 The test framework orchestrates test execution, measurement logging, and
 result evaluation against limits.
 """
 from abc import ABC, abstractmethod
 from dataclasses import dataclass
 from typing import TYPE_CHECKING, Any
 from uuid import UUID
 from py_dvt_ate.data.models import TestStatus
 if TYPE_CHECKING:
    # Avoid circular imports while maintaining type checking
    from py_dvt_ate.framework.logger import ITestLogger
    from py_dvt_ate.instruments.factory import InstrumentSet
@dataclass
 class TestContext:
    """Runtime context for test execution.
    Provides access to instruments, logging, and configuration during test
    execution. Passed to each test's execute() method.
    Attributes:
        run_id: Unique identifier for this test run (UUID).
        instruments: Hardware abstraction layer providing access to all instruments.
        logger: Test logger for recording measurements and events.
        config: Test-specific configuration dictionary.
    """
    run_id: UUID
    instruments: "InstrumentSet"
    logger: "ITestLogger"
    config: dict[str, Any]
 class ITest(ABC):
    """Abstract base class for DVT test implementations.
    All characterisation tests must inherit from this class and implement
    the required properties and methods. The test runner uses these to
    discover, describe, and execute tests.
    Example:
        class TempCoTest(ITest):
            @property
            def name(self) -> str:
                return "tempco"
            @property
            def description(self) -> str:
                return "Output voltage temperature coefficient"
            def execute(self, context: TestContext) -> TestStatus:
                # Test implementation...
                return TestStatus.PASSED
    """
    @property
    @abstractmethod
    def name(self) -> str:
        """Return the unique test identifier.
        Used for test discovery and selection. Should be lowercase,
        alphanumeric with underscores (e.g., "tempco", "load_regulation").
        Returns:
            Unique test name string.
        """
        pass
    @property
    @abstractmethod
    def description(self) -> str:
        """Return a human-readable test description.
        Describes what the test measures or characterises. Displayed in
        reports and user interfaces.
        Returns:
            Brief description of the test purpose.
        """
        pass
    @abstractmethod
    def execute(self, context: TestContext) -> TestStatus:
        """Execute the test with the given context.
        Contains the test logic: configure instruments, take measurements,
        log results, and evaluate pass/fail. The test should use the
        context.logger to record measurements and context.instruments to
        control equipment.
        Args:
            context: Runtime context with instruments, logger, and config.
        Returns:
            Final test status (PASSED, FAILED, ERROR, etc.).
        Raises:
            Exception: If a critical error occurs during test execution.
                      The test runner will catch this and mark the test as ERROR.
        """
        pass
--- a/src/py_dvt_ate/framework/limits.py
+++ b/src/py_dvt_ate/framework/limits.py
@@ -0,0 +1,238 @@
 """Limit checking utilities for test result evaluation.
 This module provides utilities for evaluating measurements against specification
 limits and determining pass/fail status. Used by tests to check if results meet
 requirements and by the test runner to determine overall test status.
 """
 from dataclasses import dataclass
 from typing import Any
 from py_dvt_ate.data.models import TestResult, TestStatus
@dataclass(frozen=True)
 class Limit:
    """Specification limit for a parameter.
    Represents a single limit specification with optional lower and upper bounds.
    Used to define test specifications and evaluate pass/fail.
    Attributes:
        parameter: Parameter name this limit applies to.
        lower: Optional lower limit (inclusive). None means no lower limit.
        upper: Optional upper limit (inclusive). None means no upper limit.
        unit: Unit of measurement for the limits.
    Example:
        temp_co_limit = Limit("temp_co", lower=-50.0, upper=50.0, unit="ppm/°C")
    """
    parameter: str
    lower: float | None = None
    upper: float | None = None
    unit: str = ""
    def check(self, value: float) -> bool | None:
        """Check if a value is within this limit.
        Args:
            value: Value to check against limits.
        Returns:
            True if value is within limits, False if outside limits.
            None if no limits are defined (informational parameter).
        Example:
            limit = Limit("v_out", lower=3.25, upper=3.35, unit="V")
            limit.check(3.30)  # Returns True
            limit.check(3.40)  # Returns False
        """
        if self.lower is None and self.upper is None:
            return None
        lower_ok = self.lower is None or value >= self.lower
        upper_ok = self.upper is None or value <= self.upper
        return lower_ok and upper_ok
@dataclass(frozen=True)
 class LimitSet:
    """Collection of limits for a test.
    Groups multiple parameter limits together as a test specification.
    Can be loaded from configuration or defined programmatically.
    Attributes:
        name: Name of this limit set (e.g., "nominal", "extended").
        limits: Dictionary mapping parameter names to Limit objects.
    Example:
        limits = LimitSet(
            name="nominal",
            limits={
                "temp_co": Limit("temp_co", -50.0, 50.0, "ppm/°C"),
                "v_out": Limit("v_out", 3.25, 3.35, "V"),
            }
        )
    """
    name: str
    limits: dict[str, Limit]
    def get_limit(self, parameter: str) -> Limit | None:
        """Get the limit for a specific parameter.
        Args:
            parameter: Parameter name to look up.
        Returns:
            Limit object if found, None if parameter has no limit defined.
        """
        return self.limits.get(parameter)
    def check(self, parameter: str, value: float) -> bool | None:
        """Check if a value is within limits for a parameter.
        Args:
            parameter: Parameter name.
            value: Value to check.
        Returns:
            True if within limits, False if outside limits.
            None if parameter has no limit defined.
        """
        limit = self.get_limit(parameter)
        if limit is None:
            return None
        return limit.check(value)
    @classmethod
    def from_dict(cls, name: str, limits_dict: dict[str, Any]) -> "LimitSet":
        """Create a LimitSet from a dictionary.
        Useful for loading limit sets from YAML configuration files.
        Args:
            name: Name for this limit set.
            limits_dict: Dictionary with parameter names as keys and limit
                        specifications as values. Each limit spec should have:
                        - "lower": Optional lower limit
                        - "upper": Optional upper limit
                        - "unit": Unit of measurement
        Returns:
            LimitSet instance.
        Example:
            config = {
                "temp_co": {"lower": -50.0, "upper": 50.0, "unit": "ppm/°C"},
                "v_out": {"lower": 3.25, "upper": 3.35, "unit": "V"},
            }
            limits = LimitSet.from_dict("nominal", config)
        """
        limits = {}
        for param, spec in limits_dict.items():
            limits[param] = Limit(
                parameter=param,
                lower=spec.get("lower"),
                upper=spec.get("upper"),
                unit=spec.get("unit", ""),
            )
        return cls(name=name, limits=limits)
 def check_value(
    value: float,
    lower: float | None = None,
    upper: float | None = None,
 ) -> bool | None:
    """Check if a value is within specified limits.
    Utility function for quick limit checking without creating Limit objects.
    Args:
        value: Value to check.
        lower: Optional lower limit (inclusive).
        upper: Optional upper limit (inclusive).
    Returns:
        True if value is within limits, False if outside limits.
        None if no limits are specified.
    Example:
        check_value(3.30, lower=3.25, upper=3.35)  # Returns True
        check_value(3.40, lower=3.25, upper=3.35)  # Returns False
        check_value(3.30)  # Returns None (no limits)
    """
    if lower is None and upper is None:
        return None
    lower_ok = lower is None or value >= lower
    upper_ok = upper is None or value <= upper
    return lower_ok and upper_ok
 def evaluate_results(results: list[TestResult]) -> TestStatus:
    """Evaluate a list of test results to determine overall status.
    Aggregates multiple test results into a single pass/fail determination.
    If any result fails its limits, the overall status is FAILED.
    If all results pass (or have no limits), the overall status is PASSED.
    Args:
        results: List of TestResult objects to evaluate.
    Returns:
        TestStatus.PASSED if all results pass their limits.
        TestStatus.FAILED if any result fails its limits.
        TestStatus.PASSED if no results have limits defined (informational only).
    Example:
        results = [
            TestResult(..., value=25.0, lower_limit=-50.0, upper_limit=50.0),
            TestResult(..., value=3.30, lower_limit=3.25, upper_limit=3.35),
        ]
        status = evaluate_results(results)  # Returns TestStatus.PASSED
    """
    if not results:
        return TestStatus.PASSED
    # Check if any result failed
    for result in results:
        if result.passed is False:
            return TestStatus.FAILED
    # All results passed (or had no limits)
    return TestStatus.PASSED
 def format_limit_violation(result: TestResult) -> str:
    """Format a limit violation message for a failed result.
    Creates a human-readable message describing why a result failed.
    Useful for logging and reporting.
    Args:
        result: TestResult that failed its limits.
    Returns:
        Formatted violation message.
    Example:
        result = TestResult(..., parameter="v_out", value=3.40,
                           lower_limit=3.25, upper_limit=3.35, unit="V")
        message = format_limit_violation(result)
        # Returns: "v_out: 3.400 V [FAIL] (limits: 3.250 to 3.350 V)"
    """
    status = "PASS" if result.passed else "FAIL"
    limits_str = ""
    if result.lower_limit is not None and result.upper_limit is not None:
        limits_str = f" (limits: {result.lower_limit:.3f} to {result.upper_limit:.3f} {result.unit})"
    elif result.lower_limit is not None:
        limits_str = f" (minimum: {result.lower_limit:.3f} {result.unit})"
    elif result.upper_limit is not None:
        limits_str = f" (maximum: {result.upper_limit:.3f} {result.unit})"
    return f"{result.parameter}: {result.value:.3f} {result.unit} [{status}]{limits_str}"
--- a/src/py_dvt_ate/framework/logger.py
+++ b/src/py_dvt_ate/framework/logger.py
@@ -0,0 +1,222 @@
 """Test logger for recording measurements and events.
 This module provides the logging infrastructure for DVT tests. The test logger
 records time-series measurements, scalar results with limits, and event messages
 during test execution.
 """
 import time
 from abc import ABC, abstractmethod
 from datetime import datetime
 from uuid import UUID
 from py_dvt_ate.data.models import Measurement
 from py_dvt_ate.data.repository import ITestRepository
 class ITestLogger(ABC):
    """Abstract interface for test data logging.
    Provides methods for logging measurements, results, and events during
    test execution. Implementations are responsible for persisting this
    data to the appropriate storage backend.
    """
    @abstractmethod
    def log_measurement(
        self,
        parameter: str,
        value: float,
        unit: str,
        conditions: dict[str, float] | None = None,
    ) -> None:
        """Log a time-series measurement with environmental conditions.
        Used for logging raw measurements taken during the test. These are
        stored as time-series data for later analysis and plotting.
        Args:
            parameter: Measurement parameter name (e.g., "v_out", "i_q").
            value: Measured value.
            unit: Unit of measurement (e.g., "V", "A", "°C").
            conditions: Optional environmental conditions at time of measurement:
                       - "temperature": Chamber temperature (°C)
                       - "input_voltage": DUT input voltage (V)
                       - "load_current": DUT load current (A)
        Example:
            logger.log_measurement(
                "v_out", 3.301, "V",
                conditions={"temperature": 25.0, "input_voltage": 5.0}
            )
        """
        pass
    @abstractmethod
    def log_result(
        self,
        parameter: str,
        value: float,
        unit: str,
        lower_limit: float | None = None,
        upper_limit: float | None = None,
    ) -> None:
        """Log a scalar test result with pass/fail limits.
        Used for logging calculated or derived results that will be evaluated
        against specification limits. These appear in test reports and determine
        overall pass/fail status.
        Args:
            parameter: Result parameter name (e.g., "temp_co", "load_reg").
            value: Calculated or measured value.
            unit: Unit of measurement (e.g., "ppm/°C", "%", "mV").
            lower_limit: Optional lower limit for pass/fail evaluation.
            upper_limit: Optional upper limit for pass/fail evaluation.
        Example:
            logger.log_result(
                "temp_co", 23.5, "ppm/°C",
                lower_limit=-50.0, upper_limit=50.0
            )
        """
        pass
    @abstractmethod
    def log_event(self, message: str, level: str = "INFO") -> None:
        """Log a test event or message.
        Used for logging informational messages, warnings, and errors during
        test execution. Useful for debugging and understanding test flow.
        Args:
            message: Event message text.
            level: Log level ("DEBUG", "INFO", "WARNING", "ERROR").
        Example:
            logger.log_event("Waiting for thermal stability", level="INFO")
        """
        pass
    @abstractmethod
    def flush(self) -> None:
        """Flush any buffered data to storage.
        Forces any buffered measurements or results to be written to the
        underlying storage backend. Called automatically at end of test,
        but can be called manually for long-running tests.
        """
        pass
 class TestLogger(ITestLogger):
    """Concrete test logger implementation using repository pattern.
    Buffers measurements in memory and writes them in batches to a
    repository for efficiency. Results and events are written immediately.
    Attributes:
        run_id: UUID of the test run this logger is associated with.
        repository: Data repository for persisting measurements and results.
        measurement_buffer: In-memory buffer of measurements awaiting write.
        buffer_size: Number of measurements to buffer before auto-flush.
    """
    def __init__(
        self,
        run_id: UUID,
        repository: ITestRepository,
        buffer_size: int = 100,
    ):
        """Initialise test logger.
        Args:
            run_id: UUID of the test run to associate logs with.
            repository: Repository for persisting data.
            buffer_size: Number of measurements to buffer before auto-flush.
                        Default 100 provides good balance of performance
                        and memory usage.
        """
        self.run_id = run_id
        self.repository = repository
        self.buffer_size = buffer_size
        self.measurement_buffer: list[Measurement] = []
    def log_measurement(
        self,
        parameter: str,
        value: float,
        unit: str,
        conditions: dict[str, float] | None = None,
    ) -> None:
        """Log a time-series measurement with environmental conditions.
        Measurements are buffered in memory and written to the repository
        in batches for efficiency.
        """
        conditions = conditions or {}
        measurement = Measurement(
            timestamp=time.time(),
            parameter=parameter,
            value=value,
            unit=unit,
            temperature=conditions.get("temperature", 0.0),
            input_voltage=conditions.get("input_voltage", 0.0),
            load_current=conditions.get("load_current", 0.0),
        )
        self.measurement_buffer.append(measurement)
        # Auto-flush when buffer is full
        if len(self.measurement_buffer) >= self.buffer_size:
            self.flush()
    def log_result(
        self,
        parameter: str,
        value: float,
        unit: str,
        lower_limit: float | None = None,
        upper_limit: float | None = None,
    ) -> None:
        """Log a scalar test result with pass/fail limits.
        Results are written immediately to the repository (not buffered).
        """
        self.repository.save_result(
            run_id=self.run_id,
            parameter=parameter,
            value=value,
            unit=unit,
            lower_limit=lower_limit,
            upper_limit=upper_limit,
        )
    def log_event(self, message: str, level: str = "INFO") -> None:
        """Log a test event or message.
        Events are currently logged to console. Future versions may
        persist events to the repository.
        """
        timestamp = datetime.now().strftime("%H:%M:%S.%f")[:-3]
        print(f"[{timestamp}] {level:7s} {message}")
    def flush(self) -> None:
        """Flush buffered measurements to repository.
        Writes all buffered measurements to the repository in a single
        batch operation, then clears the buffer.
        """
        if self.measurement_buffer:
            self.repository.save_measurements(
                run_id=self.run_id,
                measurements=self.measurement_buffer,
            )
            self.measurement_buffer.clear()
    def __del__(self) -> None:
        """Ensure buffered data is flushed on logger destruction."""
        try:
            self.flush()
        except Exception:
            # Ignore errors during cleanup
            pass
--- a/src/py_dvt_ate/framework/runner.py
+++ b/src/py_dvt_ate/framework/runner.py
@@ -0,0 +1,203 @@
 """Test runner for orchestrating DVT test execution.
 This module provides the TestRunner class, which coordinates test execution,
 manages test lifecycle, and ensures proper logging and error handling.
 """
 import json
 import traceback
 from typing import Any
 from uuid import UUID
 from py_dvt_ate.data.models import TestStatus
 from py_dvt_ate.data.repository import ITestRepository
 from py_dvt_ate.framework.context import ITest, TestContext
 from py_dvt_ate.framework.limits import evaluate_results
 from py_dvt_ate.framework.logger import TestLogger
 from py_dvt_ate.instruments.factory import InstrumentSet
 class TestRunner:
    """Orchestrates DVT test execution.
    The test runner manages the complete test lifecycle:
    1. Creates a test run record in the repository
    2. Sets up logging and context
    3. Executes the test with proper error handling
    4. Evaluates results against limits
    5. Updates final status and flushes data
    Attributes:
        repository: Data repository for persisting test results.
    Example:
        runner = TestRunner(repository)
        instruments = factory.create(config)
        run_id = runner.run_test(
            test=TempCoTest(),
            instruments=instruments,
            config={"temp_points": [-40, 25, 85]},
            operator="alice@example.com"
        )
    """
    def __init__(self, repository: ITestRepository):
        """Initialise test runner.
        Args:
            repository: Repository for persisting test data.
        """
        self.repository = repository
    def run_test(
        self,
        test: ITest,
        instruments: InstrumentSet,
        config: dict[str, Any] | None = None,
        operator: str | None = None,
        description: str | None = None,
    ) -> UUID:
        """Run a DVT test with full lifecycle management.
        Creates a test run, executes the test with proper error handling,
        evaluates results, and updates final status. All measurements and
        results are persisted to the repository.
        Args:
            test: Test instance to execute (implements ITest).
            instruments: Instrument set for test to use.
            config: Optional test-specific configuration dictionary.
            operator: Optional operator identifier (e.g., email address).
            description: Optional human-readable test run description.
        Returns:
            UUID of the test run. Can be used to retrieve results later.
        Raises:
            Exception: Only if repository operations fail. Test execution
                      errors are caught and recorded as ERROR status.
        Example:
            run_id = runner.run_test(
                test=TempCoTest(),
                instruments=instruments,
                config={"temp_points": [-40, 25, 85]},
                operator="alice@example.com",
                description="Characterisation run #42"
            )
            print(f"Test run ID: {run_id}")
        """
        config = config or {}
        # Create test run record
        run_id = self.repository.create_run(
            test_name=test.name,
            config=config,
            operator=operator,
            description=description or test.description,
        )
        # Create logger for this run
        logger = TestLogger(run_id=run_id, repository=self.repository)
        # Create test context
        context = TestContext(
            run_id=run_id,
            instruments=instruments,
            logger=logger,
            config=config,
        )
        # Update status to running
        self.repository.update_run_status(run_id, TestStatus.RUNNING)
        # Execute test with error handling
        try:
            logger.log_event(f"Starting test: {test.name}", level="INFO")
            logger.log_event(f"Description: {test.description}", level="INFO")
            # Log configuration
            if config:
                config_str = json.dumps(config, indent=2)
                logger.log_event(f"Configuration:\n{config_str}", level="DEBUG")
            # Execute the test
            status = test.execute(context)
            # Flush any buffered measurements
            logger.flush()
            # Evaluate results if test didn't explicitly set status
            if status == TestStatus.RUNNING:
                results = self.repository.get_results(run_id)
                status = evaluate_results(results)
                logger.log_event(
                    f"Test completed. Evaluated {len(results)} results: {status.value}",
                    level="INFO",
                )
            # Update final status
            self.repository.complete_run(run_id, status)
            logger.log_event(f"Test finished with status: {status.value}", level="INFO")
        except KeyboardInterrupt:
            # User interrupted - mark as error but don't swallow interrupt
            logger.log_event("Test interrupted by user", level="WARNING")
            logger.flush()
            self.repository.complete_run(run_id, TestStatus.ERROR)
            raise
        except Exception as e:
            # Test execution error - log and mark as ERROR
            error_msg = f"Test execution failed: {e}"
            logger.log_event(error_msg, level="ERROR")
            logger.log_event(traceback.format_exc(), level="DEBUG")
            logger.flush()
            self.repository.complete_run(run_id, TestStatus.ERROR)
            logger.log_event("Test finished with status: ERROR", level="INFO")
        return run_id
    def run_tests(
        self,
        tests: list[ITest],
        instruments: InstrumentSet,
        config: dict[str, Any] | None = None,
        operator: str | None = None,
    ) -> list[UUID]:
        """Run multiple tests sequentially.
        Convenience method for running a suite of tests. Each test is run
        independently with its own test run record. If one test fails, the
        remaining tests still execute.
        Args:
            tests: List of test instances to execute.
            instruments: Instrument set shared by all tests.
            config: Optional configuration applied to all tests.
            operator: Optional operator identifier.
        Returns:
            List of test run UUIDs in execution order.
        Example:
            run_ids = runner.run_tests(
                tests=[TempCoTest(), LoadRegTest(), LineRegTest()],
                instruments=instruments,
                config={"common_setting": 42},
                operator="alice@example.com"
            )
            for run_id in run_ids:
                run = repository.get_run(run_id)
                print(f"{run.test_name}: {run.status.value}")
        """
        run_ids = []
        for test in tests:
            run_id = self.run_test(
                test=test,
                instruments=instruments,
                config=config,
                operator=operator,
            )
            run_ids.append(run_id)
        return run_ids
--- a/src/py_dvt_ate/hal/init.py
+++ b/src/py_dvt_ate/hal/init.py
@@ -1 +0,0 @@
 """Hardware Abstraction Layer."""
--- a/src/py_dvt_ate/hal/impl/init.py
+++ b/src/py_dvt_ate/hal/impl/init.py
@@ -1 +0,0 @@
 """HAL implementations."""
--- a/src/py_dvt_ate/instruments/init.py
+++ b/src/py_dvt_ate/instruments/init.py
@@ -1 +1,29 @@
-"""Virtual instrument implementations."""
+"""Instrument control package.
 This package provides everything needed to communicate with lab instruments:
 - Protocol interfaces (IThermalChamber, IPowerSupply, IMultimeter)
 - SCPI command parsing
 - Transport layer (TCP, VISA)
 - Instrument drivers
 - Factory for creating configured instrument sets
 """
 from py_dvt_ate.instruments.factory import (
    InstrumentConfig,
    InstrumentFactory,
    InstrumentSet,
 )
 from py_dvt_ate.instruments.interfaces import (
    IMultimeter,
    IPowerSupply,
    IThermalChamber,
 )
 __all__ = [
    "IThermalChamber",
    "IPowerSupply",
    "IMultimeter",
    "InstrumentSet",
    "InstrumentConfig",
    "InstrumentFactory",
 ]
--- a/src/py_dvt_ate/instruments/drivers/init.py
+++ b/src/py_dvt_ate/instruments/drivers/init.py
@@ -0,0 +1,17 @@
 """SCPI driver implementations for lab instruments.
 Each driver translates high-level operations into SCPI commands
 and handles responses from instruments.
 """
 from py_dvt_ate.instruments.drivers.base import BaseDriver
 from py_dvt_ate.instruments.drivers.chamber import ThermalChamberDriver
 from py_dvt_ate.instruments.drivers.multimeter import MultimeterDriver
 from py_dvt_ate.instruments.drivers.power_supply import PowerSupplyDriver
 __all__ = [
    "BaseDriver",
    "ThermalChamberDriver",
    "PowerSupplyDriver",
    "MultimeterDriver",
 ]
--- a/src/py_dvt_ate/instruments/drivers/base.py
+++ b/src/py_dvt_ate/instruments/drivers/base.py
@@ -0,0 +1,197 @@
 """Base class for SCPI instrument drivers.
 This module provides the foundation for implementing client-side instrument
 drivers that communicate via SCPI commands over a transport layer.
 """
 from typing import TYPE_CHECKING
 if TYPE_CHECKING:
    from py_dvt_ate.instruments.transport.base import Transport
 class BaseDriver:
    """Base class for SCPI instrument drivers.
    Provides common functionality for communicating with instruments via
    SCPI commands. Subclasses implement instrument-specific command methods.
    All drivers depend on a Transport instance for low-level communication.
    Attributes:
        transport: The transport layer for communication.
    """
    def __init__(self, transport: "Transport") -> None:
        """Initialise the driver with a transport layer.
        Args:
            transport: Transport instance for communication (TCP, VISA, etc.).
        """
        self.transport = transport
    def connect(self) -> None:
        """Establish connection to the instrument.
        Raises:
            ConnectionError: If connection fails.
        """
        self.transport.connect()
    def disconnect(self) -> None:
        """Close connection to the instrument.
        Safe to call multiple times (idempotent).
        """
        self.transport.disconnect()
    @property
    def is_connected(self) -> bool:
        """Check if connection is active.
        Returns:
            True if connected, False otherwise.
        """
        return self.transport.is_connected
    def write(self, command: str) -> None:
        """Send a SCPI command to the instrument.
        Args:
            command: SCPI command string (without terminator).
        Raises:
            ConnectionError: If not connected.
            IOError: If write fails.
        """
        self.transport.write(command)
    def query(self, command: str, timeout: float | None = None) -> str:
        """Send a SCPI query and read the response.
        Args:
            command: SCPI query string (without terminator).
            timeout: Read timeout in seconds. None uses default.
        Returns:
            Response string from instrument.
        Raises:
            ConnectionError: If not connected.
            TimeoutError: If read times out.
            IOError: If communication fails.
        """
        return self.transport.query(command, timeout)
    def query_float(self, command: str, timeout: float | None = None) -> float:
        """Send a SCPI query and parse response as float.
        Args:
            command: SCPI query string.
            timeout: Read timeout in seconds.
        Returns:
            Parsed floating-point value.
        Raises:
            ConnectionError: If not connected.
            TimeoutError: If read times out.
            IOError: If communication fails.
            ValueError: If response cannot be parsed as float.
        """
        response = self.query(command, timeout)
        try:
            return float(response.strip())
        except ValueError as err:
            raise ValueError(f"Cannot parse '{response}' as float") from err
    def query_int(self, command: str, timeout: float | None = None) -> int:
        """Send a SCPI query and parse response as integer.
        Args:
            command: SCPI query string.
            timeout: Read timeout in seconds.
        Returns:
            Parsed integer value.
        Raises:
            ConnectionError: If not connected.
            TimeoutError: If read times out.
            IOError: If communication fails.
            ValueError: If response cannot be parsed as integer.
        """
        response = self.query(command, timeout)
        try:
            return int(response.strip())
        except ValueError as err:
            raise ValueError(f"Cannot parse '{response}' as int") from err
    def query_bool(self, command: str, timeout: float | None = None) -> bool:
        """Send a SCPI query and parse response as boolean.
        Interprets "1", "ON", "TRUE" as True; "0", "OFF", "FALSE" as False.
        Args:
            command: SCPI query string.
            timeout: Read timeout in seconds.
        Returns:
            Parsed boolean value.
        Raises:
            ConnectionError: If not connected.
            TimeoutError: If read times out.
            IOError: If communication fails.
            ValueError: If response cannot be parsed as boolean.
        """
        response = self.query(command, timeout).strip().upper()
        if response in ("1", "ON", "TRUE"):
            return True
        if response in ("0", "OFF", "FALSE"):
            return False
        raise ValueError(f"Cannot parse '{response}' as bool")
    def identify(self) -> str:
        """Query instrument identification (*IDN?).
        Returns:
            Identification string in format:
            "Manufacturer,Model,SerialNumber,FirmwareVersion"
        Raises:
            ConnectionError: If not connected.
            IOError: If communication fails.
        """
        return self.query("*IDN?")
    def reset(self) -> None:
        """Reset instrument to default state (*RST).
        Raises:
            ConnectionError: If not connected.
            IOError: If communication fails.
        """
        self.write("*RST")
    def clear_status(self) -> None:
        """Clear instrument status (*CLS).
        Raises:
            ConnectionError: If not connected.
            IOError: If communication fails.
        """
        self.write("*CLS")
    def operation_complete(self) -> bool:
        """Query operation complete status (*OPC?).
        Returns:
            True if operation complete.
        Raises:
            ConnectionError: If not connected.
            IOError: If communication fails.
        """
        response = self.query("*OPC?")
        return response.strip() == "1"
--- a/src/py_dvt_ate/instruments/drivers/chamber.py
+++ b/src/py_dvt_ate/instruments/drivers/chamber.py
@@ -0,0 +1,142 @@
 """Thermal chamber SCPI driver.
 This module implements a client-side driver for thermal chambers that
 communicate via SCPI commands.
 """
 import time
 from py_dvt_ate.instruments.drivers.base import BaseDriver
 from py_dvt_ate.instruments.interfaces import IThermalChamber
 class ThermalChamberDriver(BaseDriver, IThermalChamber):
    """SCPI driver for thermal chambers.
    Provides high-level Python API for controlling thermal chambers via
    SCPI commands. Implements the IThermalChamber interface.
    SCPI Commands Used:
        TEMP:SETPOINT <value>  - Set target temperature (°C)
        TEMP:SETPOINT?         - Query current setpoint
        TEMP:ACTUAL?           - Query actual chamber temperature
        TEMP:STAB?             - Query stability (1=stable, 0=settling)
        TEMP:RAMP <rate>       - Set temperature ramp rate (°C/min)
        TEMP:RAMP?             - Query ramp rate
    Example:
        >>> transport = TCPTransport("localhost", 5001)
        >>> chamber = ThermalChamberDriver(transport)
        >>> chamber.connect()
        >>> chamber.set_temperature(85.0)
        >>> chamber.wait_until_stable(timeout=600.0)
        >>> temp = chamber.get_temperature()
    """
    def set_temperature(self, setpoint: float) -> None:
        """Set the chamber temperature setpoint.
        Args:
            setpoint: Target temperature in degrees Celsius.
        Raises:
            ConnectionError: If not connected.
            IOError: If command fails.
        """
        self.write(f"TEMP:SETPOINT {setpoint:.2f}")
    def get_temperature(self) -> float:
        """Get the actual chamber temperature.
        Returns:
            Current chamber temperature in degrees Celsius.
        Raises:
            ConnectionError: If not connected.
            IOError: If query fails.
        """
        return self.query_float("TEMP:ACTUAL?")
    def get_setpoint(self) -> float:
        """Get the current temperature setpoint.
        Returns:
            Current setpoint in degrees Celsius.
        Raises:
            ConnectionError: If not connected.
            IOError: If query fails.
        """
        return self.query_float("TEMP:SETPOINT?")
    def is_stable(self) -> bool:
        """Check if chamber temperature is stable.
        Temperature is considered stable when it has settled within
        the instrument's configured stability threshold of the setpoint.
        Returns:
            True if temperature is stable, False if still settling.
        Raises:
            ConnectionError: If not connected.
            IOError: If query fails.
        """
        return self.query_bool("TEMP:STAB?")
    def wait_until_stable(
        self, timeout: float = 300.0, poll_interval: float = 1.0
    ) -> bool:
        """Wait until chamber temperature stabilises.
        Polls the stability status at regular intervals until stable
        or timeout is reached.
        Args:
            timeout: Maximum time to wait in seconds. Default 300s (5 minutes).
            poll_interval: Time between stability checks in seconds. Default 1s.
        Returns:
            True if temperature stabilised within timeout, False if timed out.
        Raises:
            ConnectionError: If not connected.
            IOError: If communication fails.
            ValueError: If timeout or poll_interval are negative.
        """
        if timeout < 0:
            raise ValueError("Timeout must be non-negative")
        if poll_interval <= 0:
            raise ValueError("Poll interval must be positive")
        start_time = time.time()
        while time.time() - start_time < timeout:
            if self.is_stable():
                return True
            time.sleep(poll_interval)
        return False
    def set_ramp_rate(self, rate: float) -> None:
        """Set the temperature ramp rate.
        Args:
            rate: Ramp rate in degrees Celsius per minute.
        Raises:
            ConnectionError: If not connected.
            IOError: If command fails.
        """
        self.write(f"TEMP:RAMP {rate:.2f}")
    def get_ramp_rate(self) -> float:
        """Get the current temperature ramp rate.
        Returns:
            Ramp rate in degrees Celsius per minute.
        Raises:
            ConnectionError: If not connected.
            IOError: If query fails.
        """
        return self.query_float("TEMP:RAMP?")
--- a/src/py_dvt_ate/instruments/drivers/multimeter.py
+++ b/src/py_dvt_ate/instruments/drivers/multimeter.py
@@ -0,0 +1,158 @@
 """Multimeter SCPI driver.
 This module implements a client-side driver for digital multimeters
 that communicate via SCPI commands.
 """
 from py_dvt_ate.instruments.drivers.base import BaseDriver
 from py_dvt_ate.instruments.interfaces import IMultimeter
 class MultimeterDriver(BaseDriver, IMultimeter):
    """SCPI driver for digital multimeters.
    Provides high-level Python API for making measurements with DMMs via
    SCPI commands. Implements the IMultimeter interface.
    SCPI Commands Used:
        MEAS:VOLT:DC?      - Measure DC voltage
        MEAS:CURR:DC?      - Measure DC current
        CONF:VOLT:DC       - Configure for DC voltage measurement
        CONF:CURR:DC       - Configure for DC current measurement
        CONF?              - Query current configuration
        READ?              - Take measurement with current configuration
    Example:
        >>> transport = TCPTransport("localhost", 5003)
        >>> dmm = MultimeterDriver(transport)
        >>> dmm.connect()
        >>> voltage = dmm.measure_dc_voltage()
        >>> current = dmm.measure_dc_current()
    """
    def measure_dc_voltage(self, range: str = "AUTO") -> float:
        """Measure DC voltage.
        Configures the meter for DC voltage and takes a measurement.
        Args:
            range: Measurement range. Default "AUTO" for auto-ranging.
                  Note: Range parameter currently not supported by simulator.
        Returns:
            Measured voltage in volts.
        Raises:
            ConnectionError: If not connected.
            IOError: If query fails.
        """
        # Note: Range parameter not yet implemented in virtual instrument
        return self.query_float("MEAS:VOLT:DC?")
    def measure_dc_current(self, range: str = "AUTO") -> float:
        """Measure DC current.
        Configures the meter for DC current and takes a measurement.
        Args:
            range: Measurement range. Default "AUTO" for auto-ranging.
                  Note: Range parameter currently not supported by simulator.
        Returns:
            Measured current in amps.
        Raises:
            ConnectionError: If not connected.
            IOError: If query fails.
        """
        # Note: Range parameter not yet implemented in virtual instrument
        return self.query_float("MEAS:CURR:DC?")
    def measure_resistance(self, range: str = "AUTO") -> float:
        """Measure resistance.
        Configures the meter for resistance and takes a measurement.
        Args:
            range: Measurement range. Default "AUTO" for auto-ranging.
        Returns:
            Measured resistance in ohms.
        Raises:
            ConnectionError: If not connected.
            IOError: If query fails.
            NotImplementedError: If instrument does not support resistance.
        """
        # Note: Resistance measurement not yet implemented in virtual instrument
        raise NotImplementedError(
            "Resistance measurement not yet supported by virtual instrument"
        )
    def set_integration_time(self, nplc: float) -> None:
        """Set the integration time.
        Args:
            nplc: Integration time in number of power line cycles (NPLC).
                 Typical values: 0.02, 0.2, 1, 10, 100.
        Raises:
            ConnectionError: If not connected.
            IOError: If command fails.
            NotImplementedError: If instrument does not support integration time.
        """
        # Note: Integration time not yet implemented in virtual instrument
        raise NotImplementedError(
            "Integration time setting not yet supported by virtual instrument"
        )
    def configure_dc_voltage(self) -> None:
        """Configure meter for DC voltage measurement.
        Sets the measurement function without taking a measurement.
        Use read() to take a measurement after configuring.
        Raises:
            ConnectionError: If not connected.
            IOError: If command fails.
        """
        self.write("CONF:VOLT:DC")
    def configure_dc_current(self) -> None:
        """Configure meter for DC current measurement.
        Sets the measurement function without taking a measurement.
        Use read() to take a measurement after configuring.
        Raises:
            ConnectionError: If not connected.
            IOError: If command fails.
        """
        self.write("CONF:CURR:DC")
    def get_configuration(self) -> str:
        """Get the current measurement configuration.
        Returns:
            Configuration string (e.g., "VOLT:DC", "CURR:DC").
        Raises:
            ConnectionError: If not connected.
            IOError: If query fails.
        """
        return self.query("CONF?").strip('"')
    def read(self) -> float:
        """Take a measurement using the current configuration.
        Must call configure_dc_voltage() or configure_dc_current() first
        to set the measurement function.
        Returns:
            Measured value (voltage in V or current in A).
        Raises:
            ConnectionError: If not connected.
            IOError: If query fails.
        """
        return self.query_float("READ?")
--- a/src/py_dvt_ate/instruments/drivers/power_supply.py
+++ b/src/py_dvt_ate/instruments/drivers/power_supply.py
@@ -0,0 +1,153 @@
 """Power supply SCPI driver.
 This module implements a client-side driver for programmable power supplies
 that communicate via SCPI commands.
 """
 from py_dvt_ate.instruments.drivers.base import BaseDriver
 from py_dvt_ate.instruments.interfaces import IPowerSupply
 class PowerSupplyDriver(BaseDriver, IPowerSupply):
    """SCPI driver for programmable power supplies.
    Provides high-level Python API for controlling power supplies via
    SCPI commands. Implements the IPowerSupply interface.
    Note: This driver assumes a single-channel instrument. The channel
    parameter is accepted for interface compatibility but currently ignored.
    SCPI Commands Used:
        VOLT <value>       - Set output voltage (V)
        VOLT?              - Query voltage setpoint
        CURR <value>       - Set current limit (A)
        CURR?              - Query current limit
        OUTP <ON|OFF|1|0>  - Enable/disable output
        OUTP?              - Query output state (1=on, 0=off)
        MEAS:VOLT?         - Measure actual output voltage
        MEAS:CURR?         - Measure actual output current
    Example:
        >>> transport = TCPTransport("localhost", 5002)
        >>> psu = PowerSupplyDriver(transport)
        >>> psu.connect()
        >>> psu.set_voltage(1, 3.3)
        >>> psu.set_current_limit(1, 0.5)
        >>> psu.enable_output(1, True)
        >>> voltage = psu.measure_voltage(1)
    """
    def set_voltage(self, channel: int, voltage: float) -> None:
        """Set the output voltage setpoint.
        Args:
            channel: Channel number (currently ignored, single channel assumed).
            voltage: Target voltage in volts.
        Raises:
            ConnectionError: If not connected.
            IOError: If command fails.
        """
        self.write(f"VOLT {voltage:.3f}")
    def get_voltage(self, channel: int) -> float:
        """Get the voltage setpoint.
        Args:
            channel: Channel number (currently ignored, single channel assumed).
        Returns:
            Current voltage setpoint in volts.
        Raises:
            ConnectionError: If not connected.
            IOError: If query fails.
        """
        return self.query_float("VOLT?")
    def set_current_limit(self, channel: int, current: float) -> None:
        """Set the current limit.
        Args:
            channel: Channel number (currently ignored, single channel assumed).
            current: Current limit in amps.
        Raises:
            ConnectionError: If not connected.
            IOError: If command fails.
        """
        self.write(f"CURR {current:.3f}")
    def get_current_limit(self, channel: int) -> float:
        """Get the current limit.
        Args:
            channel: Channel number (currently ignored, single channel assumed).
        Returns:
            Current limit in amps.
        Raises:
            ConnectionError: If not connected.
            IOError: If query fails.
        """
        return self.query_float("CURR?")
    def measure_voltage(self, channel: int) -> float:
        """Measure the actual output voltage.
        Args:
            channel: Channel number (currently ignored, single channel assumed).
        Returns:
            Measured voltage in volts.
        Raises:
            ConnectionError: If not connected.
            IOError: If query fails.
        """
        return self.query_float("MEAS:VOLT?")
    def measure_current(self, channel: int) -> float:
        """Measure the actual output current.
        Args:
            channel: Channel number (currently ignored, single channel assumed).
        Returns:
            Measured current in amps.
        Raises:
            ConnectionError: If not connected.
            IOError: If query fails.
        """
        return self.query_float("MEAS:CURR?")
    def enable_output(self, channel: int, enable: bool) -> None:
        """Enable or disable the output.
        Args:
            channel: Channel number (currently ignored, single channel assumed).
            enable: True to enable output, False to disable.
        Raises:
            ConnectionError: If not connected.
            IOError: If command fails.
        """
        state = "ON" if enable else "OFF"
        self.write(f"OUTP {state}")
    def is_output_enabled(self, channel: int) -> bool:
        """Check if output is enabled.
        Args:
            channel: Channel number (currently ignored, single channel assumed).
        Returns:
            True if output is enabled, False if disabled.
        Raises:
            ConnectionError: If not connected.
            IOError: If query fails.
        """
        return self.query_bool("OUTP?")
--- a/src/py_dvt_ate/instruments/factory.py
+++ b/src/py_dvt_ate/instruments/factory.py
@@ -0,0 +1,176 @@
 """Instrument factory for creating configured instrument sets.
 This module provides a factory pattern for creating sets of instruments
 based on configuration. It abstracts away the choice between simulated
 and real hardware, allowing test code to be written once and run against
 either backend.
 """
 from dataclasses import dataclass
 from typing import Literal
 from py_dvt_ate.instruments.interfaces import IMultimeter, IPowerSupply, IThermalChamber
@dataclass
 class InstrumentSet:
    """Container for a complete set of instruments.
    Holds all instruments needed for DVT testing. All instruments implement
    the interface protocols (IThermalChamber, IPowerSupply, IMultimeter),
    allowing them to be simulated or real hardware.
    Attributes:
        chamber: Thermal chamber for temperature control.
        psu: Programmable power supply for DUT power.
        dmm: Digital multimeter for precision measurements.
    """
    chamber: IThermalChamber
    psu: IPowerSupply
    dmm: IMultimeter
@dataclass
 class InstrumentConfig:
    """Configuration for instrument connections.
    Defines how to connect to instruments. The backend determines whether
    to use simulated instruments (TCP connections to virtual instruments)
    or real hardware (PyVISA connections).
    Attributes:
        backend: "simulator" for virtual instruments, "pyvisa" for real hardware.
        Simulator Settings:
            simulator_host: Hostname/IP of simulation server. Default "localhost".
            chamber_port: TCP port for thermal chamber simulator. Default 5001.
            psu_port: TCP port for power supply simulator. Default 5002.
            dmm_port: TCP port for multimeter simulator. Default 5003.
        PyVISA Settings (for real hardware):
            chamber_visa: VISA resource string for thermal chamber (e.g., "TCPIP::192.168.1.10::INSTR").
            psu_visa: VISA resource string for power supply.
            dmm_visa: VISA resource string for multimeter.
    """
    backend: Literal["simulator", "pyvisa"]
    # Simulator settings
    simulator_host: str = "localhost"
    chamber_port: int = 5001
    psu_port: int = 5002
    dmm_port: int = 5003
    # PyVISA settings (for real hardware)
    chamber_visa: str | None = None
    psu_visa: str | None = None
    dmm_visa: str | None = None
 class InstrumentFactory:
    """Factory for creating instrument sets from configuration.
    This factory encapsulates the creation logic for instrument sets,
    hiding the complexity of instantiating transports and drivers based
    on the chosen backend.
    Example:
        >>> config = InstrumentConfig(backend="simulator")
        >>> instruments = InstrumentFactory.create(config)
        >>> instruments.chamber.set_temperature(85.0)
        >>> instruments.psu.set_voltage(1, 3.3)
        >>> voltage = instruments.dmm.measure_dc_voltage()
    """
    @staticmethod
    def create(config: InstrumentConfig) -> InstrumentSet:
        """Create instrument set based on configuration.
        Args:
            config: Configuration specifying backend and connection details.
        Returns:
            InstrumentSet containing all configured instruments.
        Raises:
            ValueError: If backend is unknown or configuration is invalid.
            ConnectionError: If unable to connect to instruments.
        """
        if config.backend == "simulator":
            return InstrumentFactory._create_simulated(config)
        elif config.backend == "pyvisa":
            return InstrumentFactory._create_pyvisa(config)
        else:
            raise ValueError(f"Unknown backend: {config.backend}")
    @staticmethod
    def _create_simulated(config: InstrumentConfig) -> InstrumentSet:
        """Create simulated instruments connected via TCP.
        Creates TCP transports for each virtual instrument and wraps them
        in SCPI drivers. The simulation server must be running and listening
        on the configured ports.
        Args:
            config: Configuration with simulator_host and port settings.
        Returns:
            InstrumentSet with simulated instruments.
        Raises:
            ConnectionError: If unable to connect to simulation server.
        """
        from py_dvt_ate.instruments.drivers.chamber import ThermalChamberDriver
        from py_dvt_ate.instruments.drivers.multimeter import MultimeterDriver
        from py_dvt_ate.instruments.drivers.power_supply import PowerSupplyDriver
        from py_dvt_ate.instruments.transport.tcp import TCPTransport
        # Create transports for each instrument
        chamber_transport = TCPTransport(config.simulator_host, config.chamber_port)
        psu_transport = TCPTransport(config.simulator_host, config.psu_port)
        dmm_transport = TCPTransport(config.simulator_host, config.dmm_port)
        # Wrap transports in drivers
        return InstrumentSet(
            chamber=ThermalChamberDriver(chamber_transport),
            psu=PowerSupplyDriver(psu_transport),
            dmm=MultimeterDriver(dmm_transport),
        )
    @staticmethod
    def _create_pyvisa(config: InstrumentConfig) -> InstrumentSet:
        """Create PyVISA instruments for real hardware.
        Creates VISA transports for each real instrument and wraps them
        in SCPI drivers. Requires PyVISA to be installed and VISA resource
        strings to be configured.
        Args:
            config: Configuration with chamber_visa, psu_visa, dmm_visa settings.
        Returns:
            InstrumentSet with real hardware instruments.
        Raises:
            NotImplementedError: PyVISA backend not yet implemented.
            ValueError: If required VISA resource strings are missing.
        """
        # Future implementation would use pyvisa.ResourceManager
        # to create VISA transports:
        #
        # import pyvisa
        # from py_dvt_ate.instruments.transport.visa import VISATransport
        #
        # rm = pyvisa.ResourceManager()
        # chamber_transport = VISATransport(rm.open_resource(config.chamber_visa))
        # psu_transport = VISATransport(rm.open_resource(config.psu_visa))
        # dmm_transport = VISATransport(rm.open_resource(config.dmm_visa))
        #
        # return InstrumentSet(
        #     chamber=ThermalChamberDriver(chamber_transport),
        #     psu=PowerSupplyDriver(psu_transport),
        #     dmm=MultimeterDriver(dmm_transport),
        # )
        raise NotImplementedError("PyVISA backend not yet implemented")
--- a/src/py_dvt_ate/instruments/interfaces.py
+++ b/src/py_dvt_ate/instruments/interfaces.py
@@ -0,0 +1,362 @@
 """Instrument interface protocols.
 This module defines the Hardware Abstraction Layer (HAL) interfaces for all
 laboratory instruments used in DVT testing. These protocols allow test code
 to be written against abstract interfaces rather than concrete implementations,
 enabling seamless switching between simulated and real hardware.
 The interfaces use ABC (Abstract Base Classes) for maximum type safety and
 explicit interface implementation. All drivers must inherit from these base
 classes and implement all abstract methods.
 """
 from abc import ABC, abstractmethod
 class IThermalChamber(ABC):
    """Hardware abstraction for thermal chambers.
    Defines the interface for controlling environmental temperature during
    thermal characterisation tests. Implementations may be virtual instruments
    (simulators) or real hardware drivers.
    Temperature units are always degrees Celsius.
    """
    @abstractmethod
    def set_temperature(self, setpoint: float) -> None:
        """Set the chamber temperature setpoint.
        Args:
            setpoint: Target temperature in degrees Celsius.
        Raises:
            ConnectionError: If not connected to instrument.
            IOError: If command fails or instrument reports error.
        """
        pass
    @abstractmethod
    def get_temperature(self) -> float:
        """Get the actual chamber temperature.
        Returns:
            Current chamber air temperature in degrees Celsius.
        Raises:
            ConnectionError: If not connected to instrument.
            IOError: If query fails or instrument reports error.
        """
        pass
    @abstractmethod
    def get_setpoint(self) -> float:
        """Get the current temperature setpoint.
        Returns:
            Current target temperature in degrees Celsius.
        Raises:
            ConnectionError: If not connected to instrument.
            IOError: If query fails or instrument reports error.
        """
        pass
    @abstractmethod
    def is_stable(self) -> bool:
        """Check if chamber temperature is stable.
        Temperature is considered stable when it has settled within
        the instrument's configured stability threshold of the setpoint
        for a minimum dwell time.
        Returns:
            True if temperature is stable, False if still settling.
        Raises:
            ConnectionError: If not connected to instrument.
            IOError: If query fails or instrument reports error.
        """
        pass
    @abstractmethod
    def wait_until_stable(
        self, timeout: float = 300.0, poll_interval: float = 1.0
    ) -> bool:
        """Wait until chamber temperature stabilises.
        Polls the stability status at regular intervals until stable
        or timeout is reached. This is a blocking call.
        Args:
            timeout: Maximum time to wait in seconds. Default 300s (5 minutes).
            poll_interval: Time between stability checks in seconds. Default 1s.
        Returns:
            True if temperature stabilised within timeout, False if timed out.
        Raises:
            ConnectionError: If not connected to instrument.
            IOError: If communication fails.
            ValueError: If timeout or poll_interval are invalid.
        """
        pass
    @abstractmethod
    def set_ramp_rate(self, rate: float) -> None:
        """Set the temperature ramp rate.
        Controls how quickly the chamber changes temperature when moving
        to a new setpoint. Slower ramp rates reduce thermal shock to DUT.
        Args:
            rate: Ramp rate in degrees Celsius per minute.
        Raises:
            ConnectionError: If not connected to instrument.
            IOError: If command fails or instrument reports error.
            ValueError: If rate is negative or exceeds instrument limits.
        """
        pass
 class IPowerSupply(ABC):
    """Hardware abstraction for programmable power supplies.
    Defines the interface for controlling DC power supplies during electrical
    characterisation tests. Implementations may be virtual instruments
    (simulators) or real hardware drivers.
    Voltage units are always volts (V).
    Current units are always amps (A).
    """
    @abstractmethod
    def set_voltage(self, channel: int, voltage: float) -> None:
        """Set the output voltage setpoint.
        Args:
            channel: Output channel number (1-based indexing).
            voltage: Target voltage in volts.
        Raises:
            ConnectionError: If not connected to instrument.
            IOError: If command fails or instrument reports error.
            ValueError: If channel is invalid or voltage out of range.
        """
        pass
    @abstractmethod
    def get_voltage(self, channel: int) -> float:
        """Get the voltage setpoint.
        Returns the programmed voltage, not the measured output voltage.
        Use measure_voltage() to get the actual output voltage.
        Args:
            channel: Output channel number (1-based indexing).
        Returns:
            Current voltage setpoint in volts.
        Raises:
            ConnectionError: If not connected to instrument.
            IOError: If query fails or instrument reports error.
            ValueError: If channel is invalid.
        """
        pass
    @abstractmethod
    def set_current_limit(self, channel: int, current: float) -> None:
        """Set the current limit.
        The supply will operate in constant voltage mode until output current
        reaches this limit, then transition to constant current mode.
        Args:
            channel: Output channel number (1-based indexing).
            current: Current limit in amps.
        Raises:
            ConnectionError: If not connected to instrument.
            IOError: If command fails or instrument reports error.
            ValueError: If channel is invalid or current out of range.
        """
        pass
    @abstractmethod
    def get_current_limit(self, channel: int) -> float:
        """Get the current limit.
        Args:
            channel: Output channel number (1-based indexing).
        Returns:
            Current limit in amps.
        Raises:
            ConnectionError: If not connected to instrument.
            IOError: If query fails or instrument reports error.
            ValueError: If channel is invalid.
        """
        pass
    @abstractmethod
    def measure_voltage(self, channel: int) -> float:
        """Measure the actual output voltage.
        Args:
            channel: Output channel number (1-based indexing).
        Returns:
            Measured output voltage in volts.
        Raises:
            ConnectionError: If not connected to instrument.
            IOError: If query fails or instrument reports error.
            ValueError: If channel is invalid.
        """
        pass
    @abstractmethod
    def measure_current(self, channel: int) -> float:
        """Measure the actual output current.
        Args:
            channel: Output channel number (1-based indexing).
        Returns:
            Measured output current in amps.
        Raises:
            ConnectionError: If not connected to instrument.
            IOError: If query fails or instrument reports error.
            ValueError: If channel is invalid.
        """
        pass
    @abstractmethod
    def enable_output(self, channel: int, enable: bool) -> None:
        """Enable or disable the output.
        Args:
            channel: Output channel number (1-based indexing).
            enable: True to enable output, False to disable.
        Raises:
            ConnectionError: If not connected to instrument.
            IOError: If command fails or instrument reports error.
            ValueError: If channel is invalid.
        """
        pass
    @abstractmethod
    def is_output_enabled(self, channel: int) -> bool:
        """Check if output is enabled.
        Args:
            channel: Output channel number (1-based indexing).
        Returns:
            True if output is enabled, False if disabled.
        Raises:
            ConnectionError: If not connected to instrument.
            IOError: If query fails or instrument reports error.
            ValueError: If channel is invalid.
        """
        pass
 class IMultimeter(ABC):
    """Hardware abstraction for digital multimeters.
    Defines the interface for making precision measurements with DMMs during
    electrical characterisation tests. Implementations may be virtual instruments
    (simulators) or real hardware drivers.
    Voltage units are always volts (V).
    Current units are always amps (A).
    Resistance units are always ohms (Ω).
    """
    @abstractmethod
    def measure_dc_voltage(self, range: str = "AUTO") -> float:
        """Measure DC voltage.
        Configures the meter for DC voltage and takes a measurement.
        Args:
            range: Measurement range. Default "AUTO" for auto-ranging.
                  Specific ranges depend on instrument capabilities.
        Returns:
            Measured voltage in volts.
        Raises:
            ConnectionError: If not connected to instrument.
            IOError: If query fails or instrument reports error.
            ValueError: If range is invalid for this instrument.
        """
        pass
    @abstractmethod
    def measure_dc_current(self, range: str = "AUTO") -> float:
        """Measure DC current.
        Configures the meter for DC current and takes a measurement.
        Args:
            range: Measurement range. Default "AUTO" for auto-ranging.
                  Specific ranges depend on instrument capabilities.
        Returns:
            Measured current in amps.
        Raises:
            ConnectionError: If not connected to instrument.
            IOError: If query fails or instrument reports error.
            ValueError: If range is invalid for this instrument.
        """
        pass
    @abstractmethod
    def measure_resistance(self, range: str = "AUTO") -> float:
        """Measure resistance.
        Configures the meter for resistance and takes a measurement.
        Args:
            range: Measurement range. Default "AUTO" for auto-ranging.
                  Specific ranges depend on instrument capabilities.
        Returns:
            Measured resistance in ohms.
        Raises:
            ConnectionError: If not connected to instrument.
            IOError: If query fails or instrument reports error.
            ValueError: If range is invalid for this instrument.
            NotImplementedError: If instrument does not support resistance.
        """
        pass
    @abstractmethod
    def set_integration_time(self, nplc: float) -> None:
        """Set the integration time.
        Integration time affects measurement accuracy and speed. Higher
        values (more power line cycles) provide better noise rejection
        but take longer to measure.
        Args:
            nplc: Integration time in number of power line cycles (NPLC).
                 Typical values: 0.02, 0.2, 1, 10, 100.
        Raises:
            ConnectionError: If not connected to instrument.
            IOError: If command fails or instrument reports error.
            ValueError: If nplc is invalid for this instrument.
            NotImplementedError: If instrument does not support integration time.
        """
        pass
--- a/src/py_dvt_ate/instruments/scpi.py
+++ b/src/py_dvt_ate/instruments/scpi.py
@@ -0,0 +1,87 @@
 """SCPI command parsing.
 This module provides SCPI (Standard Commands for Programmable Instruments)
 command parsing for instrument communication. It handles IEEE 488.2 common
 commands (*IDN?, *RST, etc.) and instrument-specific commands.
 """
 from dataclasses import dataclass
@dataclass
 class SCPICommand:
    """Parsed SCPI command.
    Attributes:
        header: The command header (e.g., "TEMP:SETPOINT" or "*IDN").
        arguments: List of command arguments (e.g., ["85.0"]).
        is_query: True if the command ends with '?' (query command).
    """
    header: str
    arguments: list[str]
    is_query: bool
    @property
    def keyword(self) -> str:
        """Return the command keyword without '?'.
        For query commands like "TEMP:SETPOINT?", returns "TEMP:SETPOINT".
        For regular commands like "VOLT", returns "VOLT".
        """
        return self.header.rstrip("?")
 class SCPIParser:
    """Parse SCPI command strings.
    Handles both IEEE 488.2 common commands (e.g., *IDN?, *RST) and
    instrument-specific commands (e.g., VOLT 3.3, TEMP:SETPOINT?).
    Examples:
        >>> parser = SCPIParser()
        >>> cmd = parser.parse("*IDN?")
        >>> cmd.header, cmd.is_query
        ('*IDN?', True)
        >>> cmd = parser.parse("VOLT 3.3")
        >>> cmd.header, cmd.arguments
        ('VOLT', ['3.3'])
    """
    def parse(self, command_string: str) -> SCPICommand:
        """Parse a SCPI command string.
        Args:
            command_string: The raw SCPI command string to parse.
        Returns:
            SCPICommand with parsed header, arguments, and query flag.
        Examples:
            "*IDN?" -> SCPICommand("*IDN?", [], True)
            "VOLT 3.3" -> SCPICommand("VOLT", ["3.3"], False)
            "TEMP:SETPOINT?" -> SCPICommand("TEMP:SETPOINT?", [], True)
            "CONF:VOLT:DC 10,0.001" -> SCPICommand("CONF:VOLT:DC", ["10", "0.001"], False)
        """
        command_string = command_string.strip()
        if not command_string:
            return SCPICommand(header="", arguments=[], is_query=False)
        # Split into header and arguments on first whitespace
        parts = command_string.split(None, 1)
        header = parts[0]
        arguments: list[str] = []
        if len(parts) > 1:
            # Parse comma-separated arguments
            arg_string = parts[1]
            arguments = [arg.strip() for arg in arg_string.split(",")]
        # Query is determined by whether the header ends with '?'
        is_query = header.endswith("?")
        return SCPICommand(
            header=header,
            arguments=arguments,
            is_query=is_query,
        )
--- a/src/py_dvt_ate/instruments/transport/init.py
+++ b/src/py_dvt_ate/instruments/transport/init.py
@@ -0,0 +1,13 @@
 """Transport layer for instrument communication.
 Provides connection abstractions for different backends:
 - TCP server for hosting SCPI instruments
 - TCP sockets (for simulation server)
 - PyVISA (for real instruments)
 """
 from py_dvt_ate.instruments.transport.base import Transport
 from py_dvt_ate.instruments.transport.server import InstrumentServer, SCPIDevice
 from py_dvt_ate.instruments.transport.tcp import TCPTransport
 __all__ = ["Transport", "TCPTransport", "InstrumentServer", "SCPIDevice"]
--- a/src/py_dvt_ate/instruments/transport/base.py
+++ b/src/py_dvt_ate/instruments/transport/base.py
@@ -0,0 +1,93 @@
 """Base transport interface for instrument communication."""
 from abc import ABC, abstractmethod
 class Transport(ABC):
    """Abstract transport interface for instrument communication.
    This abstract base class defines the interface that all transport
    implementations (TCP, VISA, etc.) must implement. It provides basic
    connection management and communication primitives for SCPI-based
    instruments.
    Implementations must inherit from this class and implement all abstract
    methods.
    """
    @abstractmethod
    def connect(self) -> None:
        """Establish connection to instrument.
        Raises:
            ConnectionError: If connection fails.
        """
        pass
    @abstractmethod
    def disconnect(self) -> None:
        """Close connection to instrument.
        Should be idempotent - safe to call multiple times.
        """
        pass
    @abstractmethod
    def write(self, command: str) -> None:
        """Send command to instrument.
        Args:
            command: SCPI command string to send (without terminator).
        Raises:
            ConnectionError: If not connected.
            IOError: If write fails.
        """
        pass
    @abstractmethod
    def read(self, timeout: float | None = None) -> str:
        """Read response from instrument.
        Args:
            timeout: Read timeout in seconds. None uses default.
        Returns:
            Response string from instrument (without terminator).
        Raises:
            ConnectionError: If not connected.
            TimeoutError: If read times out.
            IOError: If read fails.
        """
        pass
    @abstractmethod
    def query(self, command: str, timeout: float | None = None) -> str:
        """Send command and read response.
        Convenience method combining write() and read().
        Args:
            command: SCPI command string to send.
            timeout: Read timeout in seconds. None uses default.
        Returns:
            Response string from instrument.
        Raises:
            ConnectionError: If not connected.
            TimeoutError: If read times out.
            IOError: If communication fails.
        """
        pass
    @property
    @abstractmethod
    def is_connected(self) -> bool:
        """Check if connection is active.
        Returns:
            True if connected, False otherwise.
        """
        pass
--- a/src/py_dvt_ate/instruments/transport/server.py
+++ b/src/py_dvt_ate/instruments/transport/server.py
@@ -0,0 +1,237 @@
 """Async TCP server for exposing instruments over network.
 This module provides the InstrumentServer class that hosts SCPI
 instruments over TCP, allowing client applications to communicate using
 standard SCPI commands over a network connection.
 This is a general-purpose server that works with any object implementing
 the SCPIDevice protocol (having a process(command) -> str method).
 """
 from __future__ import annotations
 import asyncio
 import logging
 from functools import partial
 from typing import Protocol, runtime_checkable
 __all__ = ["InstrumentServer", "SCPIDevice"]
 logger = logging.getLogger(__name__)
@runtime_checkable
 class SCPIDevice(Protocol):
    """Protocol for SCPI-compatible devices.
    Any object with a process method matching this signature can be
    served by InstrumentServer.
    """
    def process(self, command: str) -> str:
        """Process a SCPI command and return the response.
        Args:
            command: SCPI command string to process.
        Returns:
            Response string (may be empty for commands with no response).
        """
        ...
 class InstrumentServer:
    """Async TCP server hosting SCPI instruments.
    Each instrument is assigned a port. Clients connect via TCP and send
    SCPI commands as newline-terminated strings. Responses are also
    newline-terminated.
    This server can host any device implementing the SCPIDevice protocol,
    including both virtual instruments (simulators) and adapters for
    real hardware.
    Attributes:
        host: Host address to bind to.
    """
    def __init__(self, host: str = "127.0.0.1") -> None:
        """Initialise the instrument server.
        Args:
            host: Host address to bind to. Defaults to localhost.
        """
        self._host = host
        self._instruments: dict[int, SCPIDevice] = {}
        self._servers: list[asyncio.Server] = []
        self._running = False
    @property
    def host(self) -> str:
        """Get the host address."""
        return self._host
    @property
    def is_running(self) -> bool:
        """Check if server is currently running."""
        return self._running
    def register_instrument(self, port: int, instrument: SCPIDevice) -> None:
        """Register an instrument to be served on a specific port.
        Args:
            port: TCP port number to serve the instrument on.
            instrument: SCPI device to serve (any object with process method).
        Raises:
            ValueError: If port is already registered.
            RuntimeError: If server is already running.
        """
        if self._running:
            raise RuntimeError("Cannot register instruments while server is running")
        if port in self._instruments:
            raise ValueError(f"Port {port} is already registered")
        self._instruments[port] = instrument
        logger.info(
            "Registered %s on port %d",
            instrument.__class__.__name__,
            port,
        )
    def get_instrument(self, port: int) -> SCPIDevice | None:
        """Get the instrument registered on a port.
        Args:
            port: Port number to look up.
        Returns:
            Registered instrument, or None if port not registered.
        """
        return self._instruments.get(port)
    @property
    def registered_ports(self) -> list[int]:
        """Get list of registered port numbers."""
        return list(self._instruments.keys())
    async def start(self) -> None:
        """Start the server and begin listening on all registered ports.
        Creates a TCP server for each registered instrument port.
        Raises:
            RuntimeError: If server is already running or no instruments registered.
        """
        if self._running:
            raise RuntimeError("Server is already running")
        if not self._instruments:
            raise RuntimeError("No instruments registered")
        self._running = True
        for port, instrument in self._instruments.items():
            handler = partial(self._handle_client, instrument=instrument, port=port)
            server = await asyncio.start_server(
                handler,
                self._host,
                port,
            )
            self._servers.append(server)
            logger.info(
                "Started server for %s on %s:%d",
                instrument.__class__.__name__,
                self._host,
                port,
            )
    async def stop(self) -> None:
        """Stop the server and close all connections."""
        if not self._running:
            return
        for server in self._servers:
            server.close()
            await server.wait_closed()
        self._servers.clear()
        self._running = False
        logger.info("Server stopped")
    async def serve_forever(self) -> None:
        """Start the server and run until cancelled.
        This is a convenience method that starts the server and blocks
        until the server is stopped or cancelled.
        """
        await self.start()
        try:
            # Keep running until cancelled
            await asyncio.gather(
                *[server.serve_forever() for server in self._servers]
            )
        finally:
            await self.stop()
    async def _handle_client(
        self,
        reader: asyncio.StreamReader,
        writer: asyncio.StreamWriter,
        instrument: SCPIDevice,
        port: int,
    ) -> None:
        """Handle a client connection.
        Reads SCPI commands (newline-terminated), processes them through
        the instrument, and sends back responses (newline-terminated).
        Args:
            reader: Stream reader for incoming data.
            writer: Stream writer for outgoing data.
            instrument: The instrument to process commands.
            port: Port number for logging.
        """
        addr = writer.get_extra_info("peername")
        logger.info("Client connected to port %d from %s", port, addr)
        try:
            while True:
                # Read until newline (SCPI line terminator)
                data = await reader.readline()
                if not data:
                    # Client disconnected
                    break
                # Decode and strip whitespace
                command = data.decode("utf-8").strip()
                if not command:
                    continue
                logger.debug("Port %d received: %s", port, command)
                # Process command through instrument
                response = instrument.process(command)
                # Send response with newline terminator
                if response:
                    writer.write(f"{response}\n".encode())
                    await writer.drain()
                    logger.debug("Port %d sent: %s", port, response)
        except asyncio.CancelledError:
            logger.debug("Client handler cancelled for port %d", port)
        except ConnectionResetError:
            logger.debug("Client connection reset on port %d", port)
        except Exception as e:
            logger.error("Error handling client on port %d: %s", port, e)
        finally:
            writer.close()
            try:
                await writer.wait_closed()
            except Exception:
                pass
            logger.info("Client disconnected from port %d", port)
--- a/src/py_dvt_ate/instruments/transport/tcp.py
+++ b/src/py_dvt_ate/instruments/transport/tcp.py
@@ -0,0 +1,195 @@
 """TCP socket transport for instrument communication."""
 import socket
 from typing import Any
 from py_dvt_ate.instruments.transport.base import Transport
 class TCPTransport(Transport):
    """TCP socket transport implementation.
    Implements the Transport interface for communicating with SCPI
    instruments over TCP/IP using newline-terminated messages.
    Attributes:
        host: Hostname or IP address of the instrument.
        port: TCP port number.
        timeout: Default socket timeout in seconds.
    """
    def __init__(
        self,
        host: str,
        port: int,
        timeout: float = 5.0,
        encoding: str = "utf-8",
    ) -> None:
        """Initialise TCP transport.
        Args:
            host: Hostname or IP address.
            port: TCP port number.
            timeout: Default socket timeout in seconds.
            encoding: Text encoding for commands and responses.
        """
        self._host = host
        self._port = port
        self._timeout = timeout
        self._encoding = encoding
        self._socket: socket.socket | None = None
    @property
    def host(self) -> str:
        """Get the host address."""
        return self._host
    @property
    def port(self) -> int:
        """Get the port number."""
        return self._port
    @property
    def is_connected(self) -> bool:
        """Check if connection is active.
        Returns:
            True if connected, False otherwise.
        """
        return self._socket is not None
    def connect(self) -> None:
        """Establish connection to instrument.
        Raises:
            ConnectionError: If connection fails or already connected.
        """
        if self.is_connected:
            raise ConnectionError("Already connected")
        try:
            self._socket = socket.socket(socket.AF_INET, socket.SOCK_STREAM)
            self._socket.settimeout(self._timeout)
            self._socket.connect((self._host, self._port))
        except OSError as err:
            self._socket = None
            raise ConnectionError(
                f"Failed to connect to {self._host}:{self._port}: {err}"
            ) from err
    def disconnect(self) -> None:
        """Close connection to instrument.
        Safe to call multiple times (idempotent).
        """
        if self._socket is not None:
            try:
                self._socket.close()
            except OSError:
                pass  # Ignore errors during close
            finally:
                self._socket = None
    def write(self, command: str) -> None:
        """Send command to instrument.
        Commands are sent with newline terminator appended.
        Args:
            command: SCPI command string to send (without terminator).
        Raises:
            ConnectionError: If not connected.
            IOError: If write fails.
        """
        if not self.is_connected or self._socket is None:
            raise ConnectionError("Not connected")
        try:
            message = f"{command}\n".encode(self._encoding)
            self._socket.sendall(message)
        except OSError as err:
            raise OSError(f"Write failed: {err}") from err
    def read(self, timeout: float | None = None) -> str:
        """Read response from instrument.
        Reads until newline terminator is received.
        Args:
            timeout: Read timeout in seconds. None uses default.
        Returns:
            Response string from instrument (without terminator).
        Raises:
            ConnectionError: If not connected.
            TimeoutError: If read times out.
            IOError: If read fails.
        """
        if not self.is_connected or self._socket is None:
            raise ConnectionError("Not connected")
        # Set timeout if specified
        old_timeout = self._socket.gettimeout()
        if timeout is not None:
            self._socket.settimeout(timeout)
        try:
            # Read line by line (newline-terminated protocol)
            response_bytes = b""
            while True:
                chunk = self._socket.recv(1)
                if not chunk:
                    raise ConnectionError("Connection closed by remote host")
                response_bytes += chunk
                if chunk == b"\n":
                    break
            # Decode and strip whitespace
            return response_bytes.decode(self._encoding).strip()
        except ConnectionError:
            raise  # Re-raise ConnectionError as-is
        except TimeoutError as err:
            raise TimeoutError("Read timeout") from err
        except (OSError, UnicodeDecodeError) as err:
            raise OSError(f"Read failed: {err}") from err
        finally:
            # Restore original timeout
            if timeout is not None:
                self._socket.settimeout(old_timeout)
    def query(self, command: str, timeout: float | None = None) -> str:
        """Send command and read response.
        Convenience method combining write() and read().
        Args:
            command: SCPI command string to send.
            timeout: Read timeout in seconds. None uses default.
        Returns:
            Response string from instrument.
        Raises:
            ConnectionError: If not connected.
            TimeoutError: If read times out.
            IOError: If communication fails.
        """
        self.write(command)
        return self.read(timeout)
    def __enter__(self) -> "TCPTransport":
        """Context manager entry."""
        self.connect()
        return self
    def __exit__(self, *args: Any) -> None:
        """Context manager exit."""
        self.disconnect()
    def __repr__(self) -> str:
        """String representation."""
        status = "connected" if self.is_connected else "disconnected"
        return f"TCPTransport({self._host}:{self._port}, {status})"
--- a/src/py_dvt_ate/physics/init.py
+++ b/src/py_dvt_ate/physics/init.py
@@ -1 +0,0 @@
 """Physics simulation engine."""
--- a/src/py_dvt_ate/physics/dut/init.py
+++ b/src/py_dvt_ate/physics/dut/init.py
@@ -1 +0,0 @@
 """Device Under Test models."""
--- a/src/py_dvt_ate/reporting/init.py
+++ b/src/py_dvt_ate/reporting/init.py
@@ -0,0 +1,5 @@
 """Report generation.
 Generates test reports from stored data in various formats
 including PDF and HTML.
 """
--- a/src/py_dvt_ate/server/init.py
+++ b/src/py_dvt_ate/server/init.py
@@ -1 +0,0 @@
 """Simulation server."""
--- a/src/py_dvt_ate/simulation/init.py
+++ b/src/py_dvt_ate/simulation/init.py
@@ -0,0 +1,11 @@
 """Physics simulation package.
 Provides virtual instruments backed by a coupled thermal-electrical
 physics engine. Used for development and testing without real hardware.
 Note: InstrumentServer has moved to py_dvt_ate.instruments.transport
 """
 from py_dvt_ate.simulation.server import ServerConfig, SimulationServer
 __all__ = ["ServerConfig", "SimulationServer"]
--- a/src/py_dvt_ate/simulation/physics/init.py
+++ b/src/py_dvt_ate/simulation/physics/init.py
@@ -0,0 +1,5 @@
 """Physics engine for thermal-electrical simulation.
 Implements coupled thermal and electrical domain models with
 realistic time constants and temperature-dependent behaviour.
 """
--- a/src/py_dvt_ate/simulation/physics/engine.py
+++ b/src/py_dvt_ate/simulation/physics/engine.py
@@ -0,0 +1,222 @@
 """Physics engine for coupled thermal-electrical simulation.
 The physics engine maintains the simulation state and advances it
 in discrete time steps, modelling the thermal and electrical coupling
 between the DUT and its environment.
 """
 from __future__ import annotations
 from typing import TYPE_CHECKING
 from py_dvt_ate.simulation.physics.state import ElectricalState, ThermalState
 from py_dvt_ate.simulation.physics.thermal import (
    calculate_junction_temperature,
    update_case_temperature,
    update_temperature,
 )
 if TYPE_CHECKING:
    from py_dvt_ate.simulation.physics.models.base import DUTModel
 class PhysicsEngine:
    """Coupled thermal-electrical physics simulation.
    Runs at a fixed timestep, updating thermal and electrical state
    based on the DUT model and environmental conditions.
    The simulation models:
    - Chamber temperature approaching setpoint (first-order response)
    - Case temperature driven by chamber and self-heating
    - Junction temperature from case temperature and thermal resistance
    - Electrical behaviour from the DUT model (temperature-dependent)
    Attributes:
        dt: Simulation timestep in seconds.
    """
    def __init__(
        self,
        update_rate_hz: float = 100.0,
        dut_model: DUTModel | None = None,
    ) -> None:
        """Initialise the physics engine.
        Args:
            update_rate_hz: Simulation update rate in Hz. Defaults to 100.
            dut_model: DUT model to use for electrical calculations.
                       If None, a default LDO model will be used.
        """
        self.dt = 1.0 / update_rate_hz
        # Lazily import to avoid circular dependencies
        if dut_model is None:
            from py_dvt_ate.simulation.physics.models.ldo import LDOModel
            self._dut: DUTModel = LDOModel()
        else:
            self._dut = dut_model
        # Thermal parameters
        self._tau_chamber = 30.0  # seconds
        self._tau_case = 5.0  # seconds
        self._theta_jc = 15.0  # degC/W
        self._theta_ca = 5.0  # degC/W
        # State variables
        self._t_setpoint = 25.0
        self._t_chamber = 25.0
        self._t_case = 25.0
        self._v_in = 0.0
        self._i_load = 0.0
        self._output_enabled = False
        self._sim_time = 0.0
    def step(self) -> None:
        """Advance simulation by one timestep.
        Updates thermal and electrical state based on current conditions.
        The thermal-electrical coupling works as follows:
        1. Calculate current power dissipation from DUT model
        2. Update chamber temperature towards setpoint
        3. Update case temperature including self-heating
        4. Advance simulation time
        """
        # Calculate power dissipation (uses current junction temperature estimate)
        p_diss = self._calculate_power_dissipation()
        # Update chamber temperature (first-order response to setpoint)
        self._t_chamber = update_temperature(
            current_temperature=self._t_chamber,
            target_temperature=self._t_setpoint,
            time_constant=self._tau_chamber,
            dt=self.dt,
        )
        # Update case temperature (driven by chamber + self-heating)
        self._t_case = update_case_temperature(
            case_temperature=self._t_case,
            ambient_temperature=self._t_chamber,
            power_dissipation=p_diss,
            time_constant=self._tau_case,
            theta_ca=self._theta_ca,
            dt=self.dt,
        )
        # Advance simulation time
        self._sim_time += self.dt
    def get_thermal_state(self) -> ThermalState:
        """Get current thermal state snapshot.
        Returns:
            Immutable ThermalState with current temperatures.
        """
        p_diss = self._calculate_power_dissipation()
        t_junction = calculate_junction_temperature(
            case_temperature=self._t_case,
            power_dissipation=p_diss,
            theta_jc=self._theta_jc,
        )
        return ThermalState(
            chamber_temperature=self._t_chamber,
            case_temperature=self._t_case,
            junction_temperature=t_junction,
            timestamp=self._sim_time,
        )
    def get_electrical_state(self) -> ElectricalState:
        """Get current electrical state snapshot.
        Returns:
            Immutable ElectricalState with current electrical values.
        """
        p_diss = self._calculate_power_dissipation()
        t_junction = calculate_junction_temperature(
            case_temperature=self._t_case,
            power_dissipation=p_diss,
            theta_jc=self._theta_jc,
        )
        if self._output_enabled:
            v_out = self._dut.calculate_output_voltage(t_junction)
            i_q = self._dut.calculate_quiescent_current(t_junction)
            i_load = self._i_load
        else:
            v_out = 0.0
            i_q = 0.0
            i_load = 0.0
        return ElectricalState(
            input_voltage=self._v_in,
            output_voltage=v_out,
            load_current=i_load,
            quiescent_current=i_q,
            power_dissipation=p_diss,
        )
    def _calculate_power_dissipation(self) -> float:
        """Calculate current power dissipation.
        Uses the current case temperature as an approximation for junction
        temperature in the power calculation. The true junction temperature
        depends on power dissipation, creating a feedback loop that is
        resolved iteratively through the simulation steps.
        Returns:
            Power dissipation in watts.
        """
        if not self._output_enabled:
            return 0.0
        # Use case temperature as junction estimate for power calculation
        # This avoids circular dependency in the calculation
        return self._dut.calculate_power_dissipation(
            input_voltage=self._v_in,
            load_current=self._i_load,
            junction_temperature=self._t_case,
        )
    def set_chamber_setpoint(self, temperature: float) -> None:
        """Set chamber target temperature.
        Args:
            temperature: Target temperature in degrees Celsius.
        """
        self._t_setpoint = temperature
    def set_input_voltage(self, voltage: float) -> None:
        """Set DUT input voltage.
        Args:
            voltage: Input voltage in volts.
        """
        self._v_in = voltage
    def set_load_current(self, current: float) -> None:
        """Set DUT load current.
        Args:
            current: Load current in amps.
        """
        self._i_load = current
    def set_output_enabled(self, enabled: bool) -> None:
        """Enable or disable DUT power.
        Args:
            enabled: True to enable output, False to disable.
        """
        self._output_enabled = enabled
    @property
    def simulation_time(self) -> float:
        """Get current simulation time in seconds."""
        return self._sim_time
    @property
    def is_output_enabled(self) -> bool:
        """Check if DUT output is enabled."""
        return self._output_enabled
--- a/src/py_dvt_ate/simulation/physics/models/init.py
+++ b/src/py_dvt_ate/simulation/physics/models/init.py
@@ -0,0 +1,10 @@
 """Device Under Test (DUT) models.
 Provides thermal and electrical models for various device types
 including LDO regulators, op-amps, and other components.
 """
 from py_dvt_ate.simulation.physics.models.base import DUTModel
 from py_dvt_ate.simulation.physics.models.ldo import LDOModel, LDOParameters
 __all__ = ["DUTModel", "LDOModel", "LDOParameters"]
--- a/src/py_dvt_ate/simulation/physics/models/base.py
+++ b/src/py_dvt_ate/simulation/physics/models/base.py
@@ -0,0 +1,66 @@
 """Base interface for Device Under Test (DUT) models.
 Defines the interface that all DUT models must implement to integrate
 with the physics engine.
 """
 from abc import ABC, abstractmethod
 class DUTModel(ABC):
    """Abstract base class for DUT electrical/thermal models.
    DUT models encapsulate the temperature-dependent electrical behaviour
    of a device, enabling realistic simulation of thermal-electrical coupling.
    All temperature parameters are in degrees Celsius.
    All voltage parameters are in volts.
    All current parameters are in amps.
    All power parameters are in watts.
    Implementations must inherit from this class and implement all abstract
    methods.
    """
    @abstractmethod
    def calculate_output_voltage(self, junction_temperature: float) -> float:
        """Calculate the output voltage at the given junction temperature.
        Args:
            junction_temperature: DUT junction temperature in degrees Celsius.
        Returns:
            Output voltage in volts.
        """
        pass
    @abstractmethod
    def calculate_quiescent_current(self, junction_temperature: float) -> float:
        """Calculate the quiescent current at the given junction temperature.
        Args:
            junction_temperature: DUT junction temperature in degrees Celsius.
        Returns:
            Quiescent current in amps.
        """
        pass
    @abstractmethod
    def calculate_power_dissipation(
        self,
        input_voltage: float,
        load_current: float,
        junction_temperature: float,
    ) -> float:
        """Calculate the power dissipation for given operating conditions.
        Args:
            input_voltage: Input voltage in volts.
            load_current: Load current in amps.
            junction_temperature: DUT junction temperature in degrees Celsius.
        Returns:
            Power dissipation in watts.
        """
        pass
--- a/src/py_dvt_ate/simulation/physics/models/ldo.py
+++ b/src/py_dvt_ate/simulation/physics/models/ldo.py
@@ -0,0 +1,221 @@
 """LDO (Low Dropout Regulator) DUT model.
 Implements temperature-dependent electrical behaviour for an LDO voltage
 regulator, including output voltage tempco, quiescent current variation,
 and power dissipation calculations.
 """
 from dataclasses import dataclass
 from py_dvt_ate.simulation.physics.models.base import DUTModel
@dataclass(frozen=True)
 class LDOParameters:
    """Configuration parameters for an LDO model.
    All temperature coefficients are referenced to 25°C.
    Attributes:
        nominal_output_voltage: Nominal output voltage at 25°C in volts.
        tempco_ppm_per_c: Output voltage temperature coefficient in ppm/°C.
        quiescent_current_a: Quiescent current at 25°C in amps.
        quiescent_current_tempco: Quiescent current temperature coefficient (1/°C).
        dropout_voltage: Dropout voltage at 25°C in volts.
        max_output_current: Maximum output current in amps.
    """
    nominal_output_voltage: float = 3.3
    tempco_ppm_per_c: float = 50.0
    quiescent_current_a: float = 50e-6  # 50 µA
    quiescent_current_tempco: float = 0.003  # 0.3%/°C
    dropout_voltage: float = 0.3
    max_output_current: float = 0.5
 # Reference temperature for all calculations
 REFERENCE_TEMPERATURE_C = 25.0
 class LDOModel(DUTModel):
    """Temperature-dependent LDO voltage regulator model.
    Models the electrical behaviour of a linear voltage regulator with:
    - Output voltage that varies with temperature (tempco in ppm/°C)
    - Quiescent current that varies with temperature
    - Dropout voltage that increases with temperature
    - Power dissipation from (Vin - Vout) × Iload + Vin × Iq
    This class implements the DUTModel interface.
    """
    def __init__(
        self,
        params: LDOParameters | None = None,
        input_voltage: float = 5.0,
        load_current: float = 0.0,
    ) -> None:
        """Initialise the LDO model.
        Args:
            params: LDO parameters. Uses defaults if None.
            input_voltage: Initial input voltage in volts.
            load_current: Initial load current in amps.
        """
        self._params = params or LDOParameters()
        self._input_voltage = input_voltage
        self._load_current = load_current
    @property
    def params(self) -> LDOParameters:
        """Get the LDO parameters."""
        return self._params
    @property
    def input_voltage(self) -> float:
        """Get the current input voltage."""
        return self._input_voltage
    @input_voltage.setter
    def input_voltage(self, value: float) -> None:
        """Set the input voltage."""
        self._input_voltage = value
    @property
    def load_current(self) -> float:
        """Get the current load current."""
        return self._load_current
    @load_current.setter
    def load_current(self, value: float) -> None:
        """Set the load current."""
        self._load_current = value
    def calculate_output_voltage(self, junction_temperature: float) -> float:
        """Calculate the output voltage at the given junction temperature.
        Implements: V_out(T) = V_nom × (1 + TC_vout × (T - 25) × 1e-6)
        The output voltage is clamped to not exceed (Vin - Vdropout) when
        the regulator is in dropout.
        Args:
            junction_temperature: DUT junction temperature in degrees Celsius.
        Returns:
            Output voltage in volts.
        """
        delta_t = junction_temperature - REFERENCE_TEMPERATURE_C
        tempco_factor = 1.0 + self._params.tempco_ppm_per_c * delta_t * 1e-6
        ideal_vout = self._params.nominal_output_voltage * tempco_factor
        # Calculate dropout voltage at temperature
        v_dropout = self._calculate_dropout_voltage(junction_temperature)
        # Clamp output to not exceed (Vin - Vdropout)
        max_vout = max(0.0, self._input_voltage - v_dropout)
        return min(ideal_vout, max_vout)
    def calculate_quiescent_current(self, junction_temperature: float) -> float:
        """Calculate the quiescent current at the given junction temperature.
        Implements: I_q(T) = I_q_25 × (1 + TC_iq × (T - 25))
        Args:
            junction_temperature: DUT junction temperature in degrees Celsius.
        Returns:
            Quiescent current in amps.
        """
        delta_t = junction_temperature - REFERENCE_TEMPERATURE_C
        tempco_factor = 1.0 + self._params.quiescent_current_tempco * delta_t
        return self._params.quiescent_current_a * tempco_factor
    def calculate_power_dissipation(
        self,
        input_voltage: float,
        load_current: float,
        junction_temperature: float,
    ) -> float:
        """Calculate the power dissipation for given operating conditions.
        Implements: P_diss = (V_in - V_out) × I_load + V_in × I_q
        The power dissipation comes from:
        - Voltage drop across the pass element times load current
        - Quiescent current times input voltage
        Args:
            input_voltage: Input voltage in volts.
            load_current: Load current in amps.
            junction_temperature: DUT junction temperature in degrees Celsius.
        Returns:
            Power dissipation in watts.
        """
        # Temporarily set input voltage for output voltage calculation
        original_vin = self._input_voltage
        self._input_voltage = input_voltage
        try:
            v_out = self.calculate_output_voltage(junction_temperature)
            i_q = self.calculate_quiescent_current(junction_temperature)
            # Power in pass element
            p_pass = (input_voltage - v_out) * load_current
            # Power from quiescent current
            p_quiescent = input_voltage * i_q
            return p_pass + p_quiescent
        finally:
            self._input_voltage = original_vin
    def _calculate_dropout_voltage(self, junction_temperature: float) -> float:
        """Calculate the dropout voltage at the given temperature.
        Implements: V_do(T) = V_do_25 × (T_K / 300)^1.5
        where T_K is the temperature in Kelvin.
        Dropout voltage increases with temperature due to increased
        resistance of the pass element.
        Args:
            junction_temperature: Junction temperature in degrees Celsius.
        Returns:
            Dropout voltage in volts.
        """
        # Convert to Kelvin
        t_kelvin = junction_temperature + 273.15
        # Temperature ratio (reference is approximately 300K ≈ 27°C)
        temp_ratio = t_kelvin / 300.0
        return float(self._params.dropout_voltage * (temp_ratio**1.5))
    def is_in_dropout(self, junction_temperature: float) -> bool:
        """Check if the LDO is in dropout at current operating point.
        The LDO is in dropout when the input voltage minus dropout voltage
        is less than the nominal output voltage.
        Args:
            junction_temperature: Junction temperature in degrees Celsius.
        Returns:
            True if in dropout, False otherwise.
        """
        v_dropout = self._calculate_dropout_voltage(junction_temperature)
        headroom = self._input_voltage - v_dropout
        # Get the ideal (temperature-adjusted) output voltage
        delta_t = junction_temperature - REFERENCE_TEMPERATURE_C
        tempco_factor = 1.0 + self._params.tempco_ppm_per_c * delta_t * 1e-6
        ideal_vout = self._params.nominal_output_voltage * tempco_factor
        return headroom < ideal_vout
--- a/src/py_dvt_ate/simulation/physics/state.py
+++ b/src/py_dvt_ate/simulation/physics/state.py
@@ -0,0 +1,48 @@
 """Physics state dataclasses for thermal-electrical simulation.
 These immutable state snapshots represent the simulation state at a point in time.
 """
 from dataclasses import dataclass
@dataclass(frozen=True)
 class ThermalState:
    """Immutable thermal state snapshot.
    Represents the thermal conditions of the DUT and its environment
    at a specific point in simulation time.
    Attributes:
        chamber_temperature: Chamber air temperature in degrees Celsius.
        case_temperature: DUT case/package temperature in degrees Celsius.
        junction_temperature: DUT junction/die temperature in degrees Celsius.
        timestamp: Simulation time in seconds since start.
    """
    chamber_temperature: float
    case_temperature: float
    junction_temperature: float
    timestamp: float
@dataclass(frozen=True)
 class ElectricalState:
    """Immutable electrical state snapshot.
    Represents the electrical conditions of the DUT at a specific
    point in simulation time.
    Attributes:
        input_voltage: DUT input voltage in volts.
        output_voltage: DUT output voltage in volts.
        load_current: Load current drawn from DUT in amps.
        quiescent_current: DUT quiescent/bias current in amps.
        power_dissipation: Total power dissipated by DUT in watts.
    """
    input_voltage: float
    output_voltage: float
    load_current: float
    quiescent_current: float
    power_dissipation: float
--- a/src/py_dvt_ate/simulation/physics/thermal.py
+++ b/src/py_dvt_ate/simulation/physics/thermal.py
@@ -0,0 +1,193 @@
 """Thermal calculation functions for physics simulation.
 Pure functions implementing first-order thermal response calculations
 for the coupled thermal-electrical simulation.
 All temperatures are in degrees Celsius.
 All time values are in seconds.
 All power values are in watts.
 All thermal resistances are in degrees Celsius per watt (°C/W).
 """
 def calculate_temperature_derivative(
    current_temperature: float,
    target_temperature: float,
    time_constant: float,
 ) -> float:
    """Calculate the rate of temperature change for first-order response.
    Implements: dT/dt = (T_target - T_current) / τ
    Args:
        current_temperature: Current temperature in degrees Celsius.
        target_temperature: Target temperature in degrees Celsius.
        time_constant: Thermal time constant in seconds.
    Returns:
        Rate of temperature change in degrees Celsius per second.
    Raises:
        ValueError: If time_constant is not positive.
    """
    if time_constant <= 0:
        msg = f"Time constant must be positive, got {time_constant}"
        raise ValueError(msg)
    return (target_temperature - current_temperature) / time_constant
 def update_temperature(
    current_temperature: float,
    target_temperature: float,
    time_constant: float,
    dt: float,
 ) -> float:
    """Calculate new temperature after a time step using Euler integration.
    Args:
        current_temperature: Current temperature in degrees Celsius.
        target_temperature: Target temperature in degrees Celsius.
        time_constant: Thermal time constant in seconds.
        dt: Time step in seconds.
    Returns:
        New temperature in degrees Celsius after the time step.
    Raises:
        ValueError: If time_constant or dt is not positive.
    """
    if dt <= 0:
        msg = f"Time step must be positive, got {dt}"
        raise ValueError(msg)
    derivative = calculate_temperature_derivative(
        current_temperature, target_temperature, time_constant
    )
    return current_temperature + derivative * dt
 def calculate_case_temperature_derivative(
    case_temperature: float,
    ambient_temperature: float,
    power_dissipation: float,
    time_constant: float,
    theta_ca: float,
 ) -> float:
    """Calculate rate of case temperature change including self-heating.
    Implements: dT_case/dt = (T_ambient - T_case + P_diss × θ_ca) / τ_case
    The case temperature is driven by:
    - Convection/conduction to ambient (chamber) temperature
    - Self-heating from power dissipation through case-to-ambient thermal resistance
    Args:
        case_temperature: Current case temperature in degrees Celsius.
        ambient_temperature: Ambient (chamber) temperature in degrees Celsius.
        power_dissipation: Power dissipated by the device in watts.
        time_constant: Case thermal time constant in seconds.
        theta_ca: Thermal resistance from case to ambient in °C/W.
    Returns:
        Rate of case temperature change in degrees Celsius per second.
    Raises:
        ValueError: If time_constant is not positive.
    """
    if time_constant <= 0:
        msg = f"Time constant must be positive, got {time_constant}"
        raise ValueError(msg)
    # The effective target includes self-heating contribution
    thermal_drive = ambient_temperature - case_temperature + power_dissipation * theta_ca
    return thermal_drive / time_constant
 def update_case_temperature(
    case_temperature: float,
    ambient_temperature: float,
    power_dissipation: float,
    time_constant: float,
    theta_ca: float,
    dt: float,
 ) -> float:
    """Calculate new case temperature after a time step.
    Args:
        case_temperature: Current case temperature in degrees Celsius.
        ambient_temperature: Ambient (chamber) temperature in degrees Celsius.
        power_dissipation: Power dissipated by the device in watts.
        time_constant: Case thermal time constant in seconds.
        theta_ca: Thermal resistance from case to ambient in °C/W.
        dt: Time step in seconds.
    Returns:
        New case temperature in degrees Celsius after the time step.
    Raises:
        ValueError: If time_constant or dt is not positive.
    """
    if dt <= 0:
        msg = f"Time step must be positive, got {dt}"
        raise ValueError(msg)
    derivative = calculate_case_temperature_derivative(
        case_temperature,
        ambient_temperature,
        power_dissipation,
        time_constant,
        theta_ca,
    )
    return case_temperature + derivative * dt
 def calculate_junction_temperature(
    case_temperature: float,
    power_dissipation: float,
    theta_jc: float,
 ) -> float:
    """Calculate junction temperature from case temperature and power.
    The junction temperature is assumed to respond instantaneously to
    changes in case temperature and power dissipation (no thermal mass
    at the die level for this simplified model).
    Implements: T_junction = T_case + P_diss × θ_jc
    Args:
        case_temperature: Case temperature in degrees Celsius.
        power_dissipation: Power dissipated by the device in watts.
        theta_jc: Thermal resistance from junction to case in °C/W.
    Returns:
        Junction temperature in degrees Celsius.
    """
    return case_temperature + power_dissipation * theta_jc
 def calculate_steady_state_junction_temperature(
    ambient_temperature: float,
    power_dissipation: float,
    theta_jc: float,
    theta_ca: float,
 ) -> float:
    """Calculate the steady-state junction temperature.
    At steady state, the case temperature reaches equilibrium where
    the heat flow through θ_ca equals the power dissipation.
    T_case_ss = T_ambient + P_diss × θ_ca
    T_junction_ss = T_case_ss + P_diss × θ_jc
                  = T_ambient + P_diss × (θ_jc + θ_ca)
    Args:
        ambient_temperature: Ambient (chamber) temperature in degrees Celsius.
        power_dissipation: Power dissipated by the device in watts.
        theta_jc: Thermal resistance from junction to case in °C/W.
        theta_ca: Thermal resistance from case to ambient in °C/W.
    Returns:
        Steady-state junction temperature in degrees Celsius.
    """
    return ambient_temperature + power_dissipation * (theta_jc + theta_ca)
--- a/src/py_dvt_ate/simulation/server.py
+++ b/src/py_dvt_ate/simulation/server.py
@@ -0,0 +1,240 @@
 """Simulation server entry point.
 This module provides the main entry point for running the simulation server
 with all virtual instruments wired to a shared physics engine.
 """
 from __future__ import annotations
 import asyncio
 import logging
 import signal
 from dataclasses import dataclass
 from py_dvt_ate.instruments.transport import InstrumentServer
 from py_dvt_ate.simulation.physics.engine import PhysicsEngine
 from py_dvt_ate.simulation.virtual.chamber import ThermalChamberSim
 from py_dvt_ate.simulation.virtual.multimeter import MultimeterSim
 from py_dvt_ate.simulation.virtual.power_supply import PowerSupplySim
 logger = logging.getLogger(__name__)
@dataclass
 class ServerConfig:
    """Configuration for the simulation server.
    Attributes:
        host: Host address to bind to.
        chamber_port: Port for thermal chamber instrument.
        psu_port: Port for power supply instrument.
        dmm_port: Port for multimeter instrument.
        physics_rate_hz: Physics engine update rate in Hz.
    """
    host: str = "127.0.0.1"
    chamber_port: int = 5000
    psu_port: int = 5001
    dmm_port: int = 5002
    physics_rate_hz: float = 100.0
 class SimulationServer:
    """Complete simulation server with physics engine and instruments.
    Creates a physics engine and wires it to all virtual instruments,
    then exposes them over TCP for client access.
    """
    def __init__(self, config: ServerConfig | None = None) -> None:
        """Initialise the simulation server.
        Args:
            config: Server configuration. Uses defaults if not provided.
        """
        self._config = config or ServerConfig()
        self._physics_engine: PhysicsEngine | None = None
        self._instrument_server: InstrumentServer | None = None
        self._physics_task: asyncio.Task[None] | None = None
        self._running = False
    @property
    def is_running(self) -> bool:
        """Check if server is currently running."""
        return self._running
    @property
    def physics_engine(self) -> PhysicsEngine | None:
        """Get the physics engine instance."""
        return self._physics_engine
    def _setup(self) -> None:
        """Create and wire up all components."""
        # Create physics engine
        self._physics_engine = PhysicsEngine(
            update_rate_hz=self._config.physics_rate_hz
        )
        # Create instruments connected to physics engine
        chamber = ThermalChamberSim(self._physics_engine)
        psu = PowerSupplySim(self._physics_engine)
        dmm = MultimeterSim(self._physics_engine)
        # Create TCP server and register instruments
        self._instrument_server = InstrumentServer(host=self._config.host)
        self._instrument_server.register_instrument(self._config.chamber_port, chamber)
        self._instrument_server.register_instrument(self._config.psu_port, psu)
        self._instrument_server.register_instrument(self._config.dmm_port, dmm)
        logger.info(
            "Simulation server configured: chamber=%d, psu=%d, dmm=%d",
            self._config.chamber_port,
            self._config.psu_port,
            self._config.dmm_port,
        )
    async def _run_physics(self) -> None:
        """Run the physics engine simulation loop."""
        if self._physics_engine is None:
            return
        dt = self._physics_engine.dt
        while self._running:
            self._physics_engine.step()
            # Sleep for the physics timestep
            await asyncio.sleep(dt)
    async def start(self) -> None:
        """Start the simulation server.
        Sets up all components and starts the TCP server and physics engine.
        Raises:
            RuntimeError: If server is already running.
        """
        if self._running:
            raise RuntimeError("Server is already running")
        self._setup()
        self._running = True
        # Start TCP server
        if self._instrument_server is not None:
            await self._instrument_server.start()
        # Start physics engine loop
        self._physics_task = asyncio.create_task(self._run_physics())
        logger.info("Simulation server started")
    async def stop(self) -> None:
        """Stop the simulation server."""
        if not self._running:
            return
        self._running = False
        # Cancel physics loop
        if self._physics_task is not None:
            self._physics_task.cancel()
            try:
                await self._physics_task
            except asyncio.CancelledError:
                pass
            self._physics_task = None
        # Stop TCP server
        if self._instrument_server is not None:
            await self._instrument_server.stop()
            self._instrument_server = None
        self._physics_engine = None
        logger.info("Simulation server stopped")
    async def serve_forever(self) -> None:
        """Start the server and run until cancelled."""
        await self.start()
        try:
            # Wait for the physics task (which runs until cancelled)
            if self._physics_task is not None:
                await self._physics_task
        except asyncio.CancelledError:
            pass
        finally:
            await self.stop()
 async def run_server(config: ServerConfig | None = None) -> None:
    """Run the simulation server with signal handling.
    This is the main entry point for running the server. It sets up
    signal handlers for graceful shutdown.
    Args:
        config: Server configuration. Uses defaults if not provided.
    """
    server = SimulationServer(config)
    # Set up signal handlers for graceful shutdown
    loop = asyncio.get_running_loop()
    stop_event = asyncio.Event()
    def signal_handler() -> None:
        logger.info("Shutdown signal received")
        stop_event.set()
    # Register signal handlers (Unix-style, may not work on all Windows)
    try:
        for sig in (signal.SIGINT, signal.SIGTERM):
            loop.add_signal_handler(sig, signal_handler)
    except NotImplementedError:
        # Windows doesn't support add_signal_handler
        pass
    try:
        await server.start()
        logger.info("Simulation server running. Press Ctrl+C to stop.")
        # Wait for stop signal
        await stop_event.wait()
    except KeyboardInterrupt:
        logger.info("Keyboard interrupt received")
    finally:
        await server.stop()
 def main(
    host: str = "127.0.0.1",
    chamber_port: int = 5000,
    psu_port: int = 5001,
    dmm_port: int = 5002,
    physics_rate: float = 100.0,
 ) -> None:
    """Run the simulation server from command line.
    Args:
        host: Host address to bind to.
        chamber_port: Port for thermal chamber.
        psu_port: Port for power supply.
        dmm_port: Port for multimeter.
        physics_rate: Physics engine update rate in Hz.
    """
    logging.basicConfig(
        level=logging.INFO,
        format="%(asctime)s - %(name)s - %(levelname)s - %(message)s",
    )
    config = ServerConfig(
        host=host,
        chamber_port=chamber_port,
        psu_port=psu_port,
        dmm_port=dmm_port,
        physics_rate_hz=physics_rate,
    )
    asyncio.run(run_server(config))
 if __name__ == "__main__":
    main()
--- a/src/py_dvt_ate/simulation/virtual/init.py
+++ b/src/py_dvt_ate/simulation/virtual/init.py
@@ -0,0 +1,5 @@
 """Virtual instrument implementations.
 SCPI-compliant virtual instruments that respond like real hardware
 but are backed by the physics simulation engine.
 """
--- a/src/py_dvt_ate/simulation/virtual/base.py
+++ b/src/py_dvt_ate/simulation/virtual/base.py
@@ -0,0 +1,156 @@
 """Base class for virtual instrument simulators.
 This module provides the foundation for implementing SCPI-based virtual
 instruments that can be exposed over TCP for hardware abstraction testing.
 """
 from __future__ import annotations
 from abc import ABC, abstractmethod
 from collections.abc import Callable
 from typing import TYPE_CHECKING
 from py_dvt_ate.instruments.scpi import SCPICommand, SCPIParser
 if TYPE_CHECKING:
    from py_dvt_ate.simulation.physics.engine import PhysicsEngine
 # Type alias for command handlers
 CommandHandler = Callable[[SCPICommand], str]
 class BaseInstrument(ABC):
    """Abstract base class for virtual SCPI instruments.
    Provides common functionality for SCPI command parsing and dispatch.
    Subclasses should register command handlers using the register_command
    method or by overriding _setup_commands.
    Attributes:
        manufacturer: Instrument manufacturer name for *IDN? response.
        model: Instrument model name for *IDN? response.
        serial_number: Instrument serial number for *IDN? response.
        firmware_version: Firmware version for *IDN? response.
    """
    manufacturer: str = "PyDVTATE"
    model: str = "Virtual Instrument"
    serial_number: str = "SIM001"
    firmware_version: str = "1.0.0"
    def __init__(self, physics_engine: PhysicsEngine | None = None) -> None:
        """Initialise the base instrument.
        Args:
            physics_engine: Reference to physics engine for simulation state.
                           May be None for standalone operation.
        """
        self._physics_engine = physics_engine
        self._parser = SCPIParser()
        self._handlers: dict[str, CommandHandler] = {}
        self._setup_common_commands()
        self._setup_commands()
    def _setup_common_commands(self) -> None:
        """Register IEEE 488.2 common commands."""
        self.register_command("*IDN", self._handle_idn)
        self.register_command("*RST", self._handle_rst)
        self.register_command("*CLS", self._handle_cls)
        self.register_command("*OPC", self._handle_opc)
    @abstractmethod
    def _setup_commands(self) -> None:
        """Register instrument-specific command handlers.
        Subclasses must implement this method to register their
        SCPI command handlers using register_command().
        """
    def register_command(self, keyword: str, handler: CommandHandler) -> None:
        """Register a handler for a SCPI command keyword.
        Args:
            keyword: The command keyword (e.g., "TEMP:SETPOINT").
                    For commands that support both set and query forms,
                    register the base keyword without '?'.
            handler: Callable that takes SCPICommand and returns response string.
        """
        self._handlers[keyword.upper()] = handler
    def process(self, command_string: str) -> str:
        """Process a SCPI command string and return the response.
        Args:
            command_string: Raw SCPI command string to process.
        Returns:
            Response string. Empty string for commands with no response.
            Error string starting with "ERROR:" for invalid commands.
        """
        command = self._parser.parse(command_string)
        if not command.header:
            return ""
        # Look up handler by keyword (without '?' suffix)
        keyword = command.keyword.upper()
        handler = self._handlers.get(keyword)
        if handler is None:
            return f"ERROR: Unknown command '{keyword}'"
        try:
            return handler(command)
        except ValueError as e:
            return f"ERROR: {e}"
        except Exception as e:
            return f"ERROR: Internal error - {e}"
    def _handle_idn(self, command: SCPICommand) -> str:
        """Handle *IDN? identification query.
        Returns:
            Comma-separated identification string.
        """
        if not command.is_query:
            return "ERROR: *IDN is query only"
        return f"{self.manufacturer},{self.model},{self.serial_number},{self.firmware_version}"
    def _handle_rst(self, command: SCPICommand) -> str:
        """Handle *RST reset command.
        Returns:
            Empty string (no response for reset).
        """
        if command.is_query:
            return "ERROR: *RST is command only"
        self.reset()
        return ""
    def _handle_cls(self, command: SCPICommand) -> str:
        """Handle *CLS clear status command.
        Returns:
            Empty string (no response for clear).
        """
        if command.is_query:
            return "ERROR: *CLS is command only"
        return ""
    def _handle_opc(self, command: SCPICommand) -> str:
        """Handle *OPC operation complete command/query.
        Returns:
            "1" for query, empty string for command.
        """
        if command.is_query:
            return "1"
        return ""
    @abstractmethod
    def reset(self) -> None:
        """Reset instrument to default state.
        Subclasses must implement this to define reset behaviour.
        """
--- a/src/py_dvt_ate/simulation/virtual/chamber.py
+++ b/src/py_dvt_ate/simulation/virtual/chamber.py
@@ -0,0 +1,143 @@
 """Virtual thermal chamber simulator.
 This module implements a SCPI-based virtual thermal chamber that interfaces
 with the physics engine to provide realistic temperature control simulation.
 """
 from __future__ import annotations
 from typing import TYPE_CHECKING
 from py_dvt_ate.instruments.scpi import SCPICommand
 from py_dvt_ate.simulation.virtual.base import BaseInstrument
 if TYPE_CHECKING:
    from py_dvt_ate.simulation.physics.engine import PhysicsEngine
 class ThermalChamberSim(BaseInstrument):
    """Virtual thermal chamber simulator.
    Simulates a thermal chamber with SCPI control interface. The chamber
    temperature behaviour is driven by the physics engine.
    SCPI Commands:
        TEMP:SETPOINT <value>  - Set target temperature in degrees C
        TEMP:SETPOINT?         - Query current setpoint
        TEMP:ACTUAL?           - Query actual chamber temperature
        TEMP:STAB?             - Query temperature stability (1=stable, 0=settling)
    Attributes:
        manufacturer: "PyDVTATE"
        model: "TC-SIM-001"
    """
    manufacturer = "PyDVTATE"
    model = "TC-SIM-001"
    serial_number = "TCSIM001"
    firmware_version = "1.0.0"
    # Stability threshold in degrees C
    STABILITY_THRESHOLD = 0.5
    def __init__(self, physics_engine: PhysicsEngine | None = None) -> None:
        """Initialise the thermal chamber simulator.
        Args:
            physics_engine: Reference to physics engine for temperature state.
        """
        self._setpoint = 25.0  # Default setpoint
        super().__init__(physics_engine)
    def _setup_commands(self) -> None:
        """Register thermal chamber SCPI commands."""
        self.register_command("TEMP:SETPOINT", self._handle_temp_setpoint)
        self.register_command("TEMP:ACTUAL", self._handle_temp_actual)
        self.register_command("TEMP:STAB", self._handle_temp_stab)
    def reset(self) -> None:
        """Reset chamber to default state."""
        self._setpoint = 25.0
        if self._physics_engine is not None:
            self._physics_engine.set_chamber_setpoint(self._setpoint)
    def _handle_temp_setpoint(self, command: SCPICommand) -> str:
        """Handle TEMP:SETPOINT command/query.
        Args:
            command: Parsed SCPI command.
        Returns:
            Setpoint value for query, empty string for set command.
        Raises:
            ValueError: If setpoint argument is invalid.
        """
        if command.is_query:
            return f"{self._setpoint:.2f}"
        # Set command requires one argument
        if not command.arguments:
            raise ValueError("TEMP:SETPOINT requires a value")
        try:
            setpoint = float(command.arguments[0])
        except ValueError as err:
            raise ValueError(f"Invalid temperature value: {command.arguments[0]}") from err
        self._setpoint = setpoint
        if self._physics_engine is not None:
            self._physics_engine.set_chamber_setpoint(setpoint)
        return ""
    def _handle_temp_actual(self, command: SCPICommand) -> str:
        """Handle TEMP:ACTUAL? query.
        Args:
            command: Parsed SCPI command.
        Returns:
            Actual chamber temperature.
        Raises:
            ValueError: If used as command (not query).
        """
        if not command.is_query:
            raise ValueError("TEMP:ACTUAL is query only")
        if self._physics_engine is None:
            # Return setpoint if no physics engine connected
            return f"{self._setpoint:.2f}"
        thermal_state = self._physics_engine.get_thermal_state()
        return f"{thermal_state.chamber_temperature:.2f}"
    def _handle_temp_stab(self, command: SCPICommand) -> str:
        """Handle TEMP:STAB? stability query.
        Temperature is considered stable when the actual chamber temperature
        is within STABILITY_THRESHOLD of the setpoint.
        Args:
            command: Parsed SCPI command.
        Returns:
            "1" if stable, "0" if settling.
        Raises:
            ValueError: If used as command (not query).
        """
        if not command.is_query:
            raise ValueError("TEMP:STAB is query only")
        if self._physics_engine is None:
            # Assume stable if no physics engine connected
            return "1"
        thermal_state = self._physics_engine.get_thermal_state()
        error = abs(thermal_state.chamber_temperature - self._setpoint)
        if error <= self.STABILITY_THRESHOLD:
            return "1"
        return "0"
--- a/src/py_dvt_ate/simulation/virtual/multimeter.py
+++ b/src/py_dvt_ate/simulation/virtual/multimeter.py
@@ -0,0 +1,213 @@
 """Virtual digital multimeter (DMM) simulator.
 This module implements a SCPI-based virtual multimeter that interfaces
 with the physics engine to measure DUT electrical parameters.
 """
 from __future__ import annotations
 from enum import Enum
 from typing import TYPE_CHECKING
 from py_dvt_ate.instruments.scpi import SCPICommand
 from py_dvt_ate.simulation.virtual.base import BaseInstrument
 if TYPE_CHECKING:
    from py_dvt_ate.simulation.physics.engine import PhysicsEngine
 class MeasurementFunction(Enum):
    """Available measurement functions."""
    VOLTAGE_DC = "VOLT:DC"
    CURRENT_DC = "CURR:DC"
 class MultimeterSim(BaseInstrument):
    """Virtual digital multimeter simulator.
    Simulates a digital multimeter with SCPI control interface. The DMM
    measures DUT output voltage and load current via the physics engine.
    SCPI Commands:
        MEAS:VOLT:DC?      - Measure DC voltage (shortcut)
        MEAS:CURR:DC?      - Measure DC current (shortcut)
        CONF:VOLT:DC       - Configure for DC voltage measurement
        CONF:CURR:DC       - Configure for DC current measurement
        CONF?              - Query current configuration
        READ?              - Take measurement with current configuration
    Attributes:
        manufacturer: "PyDVTATE"
        model: "DMM-SIM-001"
    """
    manufacturer = "PyDVTATE"
    model = "DMM-SIM-001"
    serial_number = "DMMSIM001"
    firmware_version = "1.0.0"
    def __init__(self, physics_engine: PhysicsEngine | None = None) -> None:
        """Initialise the multimeter simulator.
        Args:
            physics_engine: Reference to physics engine for measurement values.
        """
        self._function = MeasurementFunction.VOLTAGE_DC
        super().__init__(physics_engine)
    def _setup_commands(self) -> None:
        """Register multimeter SCPI commands."""
        self.register_command("MEAS:VOLT:DC", self._handle_meas_volt_dc)
        self.register_command("MEAS:CURR:DC", self._handle_meas_curr_dc)
        self.register_command("CONF:VOLT:DC", self._handle_conf_volt_dc)
        self.register_command("CONF:CURR:DC", self._handle_conf_curr_dc)
        self.register_command("CONF", self._handle_conf)
        self.register_command("READ", self._handle_read)
    def reset(self) -> None:
        """Reset multimeter to default state."""
        self._function = MeasurementFunction.VOLTAGE_DC
    def _handle_meas_volt_dc(self, command: SCPICommand) -> str:
        """Handle MEAS:VOLT:DC? query.
        Configures for DC voltage and takes measurement in one command.
        Args:
            command: Parsed SCPI command.
        Returns:
            Measured DC voltage.
        Raises:
            ValueError: If used as command (not query).
        """
        if not command.is_query:
            raise ValueError("MEAS:VOLT:DC is query only")
        self._function = MeasurementFunction.VOLTAGE_DC
        return self._measure_voltage_dc()
    def _handle_meas_curr_dc(self, command: SCPICommand) -> str:
        """Handle MEAS:CURR:DC? query.
        Configures for DC current and takes measurement in one command.
        Args:
            command: Parsed SCPI command.
        Returns:
            Measured DC current.
        Raises:
            ValueError: If used as command (not query).
        """
        if not command.is_query:
            raise ValueError("MEAS:CURR:DC is query only")
        self._function = MeasurementFunction.CURRENT_DC
        return self._measure_current_dc()
    def _handle_conf_volt_dc(self, command: SCPICommand) -> str:
        """Handle CONF:VOLT:DC command.
        Configures multimeter for DC voltage measurement.
        Args:
            command: Parsed SCPI command.
        Returns:
            Empty string (no response for configuration).
        Raises:
            ValueError: If used as query.
        """
        if command.is_query:
            raise ValueError("CONF:VOLT:DC is command only")
        self._function = MeasurementFunction.VOLTAGE_DC
        return ""
    def _handle_conf_curr_dc(self, command: SCPICommand) -> str:
        """Handle CONF:CURR:DC command.
        Configures multimeter for DC current measurement.
        Args:
            command: Parsed SCPI command.
        Returns:
            Empty string (no response for configuration).
        Raises:
            ValueError: If used as query.
        """
        if command.is_query:
            raise ValueError("CONF:CURR:DC is command only")
        self._function = MeasurementFunction.CURRENT_DC
        return ""
    def _handle_conf(self, command: SCPICommand) -> str:
        """Handle CONF? query.
        Args:
            command: Parsed SCPI command.
        Returns:
            Current measurement configuration.
        Raises:
            ValueError: If used as command without subcommand.
        """
        if not command.is_query:
            raise ValueError("CONF requires a function (e.g., CONF:VOLT:DC)")
        return f'"{self._function.value}"'
    def _handle_read(self, command: SCPICommand) -> str:
        """Handle READ? query.
        Takes measurement using current configuration.
        Args:
            command: Parsed SCPI command.
        Returns:
            Measured value.
        Raises:
            ValueError: If used as command (not query).
        """
        if not command.is_query:
            raise ValueError("READ is query only")
        if self._function == MeasurementFunction.VOLTAGE_DC:
            return self._measure_voltage_dc()
        else:
            return self._measure_current_dc()
    def _measure_voltage_dc(self) -> str:
        """Measure DC voltage from physics engine.
        Returns:
            Formatted voltage reading.
        """
        if self._physics_engine is None:
            return "0.000000"
        electrical_state = self._physics_engine.get_electrical_state()
        return f"{electrical_state.output_voltage:.6f}"
    def _measure_current_dc(self) -> str:
        """Measure DC current from physics engine.
        Returns:
            Formatted current reading.
        """
        if self._physics_engine is None:
            return "0.000000"
        electrical_state = self._physics_engine.get_electrical_state()
        return f"{electrical_state.load_current:.6f}"
--- a/src/py_dvt_ate/simulation/virtual/power_supply.py
+++ b/src/py_dvt_ate/simulation/virtual/power_supply.py
@@ -0,0 +1,222 @@
 """Virtual power supply simulator.
 This module implements a SCPI-based virtual power supply that interfaces
 with the physics engine to provide realistic power supply simulation.
 """
 from __future__ import annotations
 from typing import TYPE_CHECKING
 from py_dvt_ate.instruments.scpi import SCPICommand
 from py_dvt_ate.simulation.virtual.base import BaseInstrument
 if TYPE_CHECKING:
    from py_dvt_ate.simulation.physics.engine import PhysicsEngine
 class PowerSupplySim(BaseInstrument):
    """Virtual power supply simulator.
    Simulates a programmable DC power supply with SCPI control interface.
    The power supply provides input voltage to the DUT via the physics engine.
    SCPI Commands:
        VOLT <value>       - Set output voltage in volts
        VOLT?              - Query voltage setpoint
        CURR <value>       - Set current limit in amps
        CURR?              - Query current limit
        OUTP <ON|OFF|1|0>  - Enable/disable output
        OUTP?              - Query output state (1=on, 0=off)
        MEAS:VOLT?         - Measure actual output voltage
        MEAS:CURR?         - Measure actual output current
    Attributes:
        manufacturer: "PyDVTATE"
        model: "PS-SIM-001"
    """
    manufacturer = "PyDVTATE"
    model = "PS-SIM-001"
    serial_number = "PSSIM001"
    firmware_version = "1.0.0"
    # Default values
    DEFAULT_VOLTAGE = 0.0
    DEFAULT_CURRENT_LIMIT = 1.0
    def __init__(self, physics_engine: PhysicsEngine | None = None) -> None:
        """Initialise the power supply simulator.
        Args:
            physics_engine: Reference to physics engine for electrical state.
        """
        self._voltage_setpoint = self.DEFAULT_VOLTAGE
        self._current_limit = self.DEFAULT_CURRENT_LIMIT
        self._output_enabled = False
        super().__init__(physics_engine)
    def _setup_commands(self) -> None:
        """Register power supply SCPI commands."""
        self.register_command("VOLT", self._handle_volt)
        self.register_command("CURR", self._handle_curr)
        self.register_command("OUTP", self._handle_outp)
        self.register_command("MEAS:VOLT", self._handle_meas_volt)
        self.register_command("MEAS:CURR", self._handle_meas_curr)
    def reset(self) -> None:
        """Reset power supply to default state."""
        self._voltage_setpoint = self.DEFAULT_VOLTAGE
        self._current_limit = self.DEFAULT_CURRENT_LIMIT
        self._output_enabled = False
        if self._physics_engine is not None:
            self._physics_engine.set_input_voltage(0.0)
            self._physics_engine.set_output_enabled(False)
    def _handle_volt(self, command: SCPICommand) -> str:
        """Handle VOLT command/query.
        Args:
            command: Parsed SCPI command.
        Returns:
            Voltage setpoint for query, empty string for set command.
        Raises:
            ValueError: If voltage argument is invalid.
        """
        if command.is_query:
            return f"{self._voltage_setpoint:.3f}"
        if not command.arguments:
            raise ValueError("VOLT requires a value")
        try:
            voltage = float(command.arguments[0])
        except ValueError as err:
            raise ValueError(f"Invalid voltage value: {command.arguments[0]}") from err
        if voltage < 0:
            raise ValueError("Voltage cannot be negative")
        self._voltage_setpoint = voltage
        if self._physics_engine is not None and self._output_enabled:
            self._physics_engine.set_input_voltage(voltage)
        return ""
    def _handle_curr(self, command: SCPICommand) -> str:
        """Handle CURR command/query.
        Args:
            command: Parsed SCPI command.
        Returns:
            Current limit for query, empty string for set command.
        Raises:
            ValueError: If current argument is invalid.
        """
        if command.is_query:
            return f"{self._current_limit:.3f}"
        if not command.arguments:
            raise ValueError("CURR requires a value")
        try:
            current = float(command.arguments[0])
        except ValueError as err:
            raise ValueError(f"Invalid current value: {command.arguments[0]}") from err
        if current < 0:
            raise ValueError("Current limit cannot be negative")
        self._current_limit = current
        return ""
    def _handle_outp(self, command: SCPICommand) -> str:
        """Handle OUTP command/query.
        Args:
            command: Parsed SCPI command.
        Returns:
            "1" or "0" for query, empty string for set command.
        Raises:
            ValueError: If output argument is invalid.
        """
        if command.is_query:
            return "1" if self._output_enabled else "0"
        if not command.arguments:
            raise ValueError("OUTP requires a value (ON, OFF, 1, or 0)")
        arg = command.arguments[0].upper()
        if arg in ("ON", "1"):
            self._output_enabled = True
        elif arg in ("OFF", "0"):
            self._output_enabled = False
        else:
            raise ValueError(f"Invalid output state: {command.arguments[0]}")
        if self._physics_engine is not None:
            self._physics_engine.set_output_enabled(self._output_enabled)
            if self._output_enabled:
                self._physics_engine.set_input_voltage(self._voltage_setpoint)
            else:
                self._physics_engine.set_input_voltage(0.0)
        return ""
    def _handle_meas_volt(self, command: SCPICommand) -> str:
        """Handle MEAS:VOLT? query.
        Args:
            command: Parsed SCPI command.
        Returns:
            Measured output voltage.
        Raises:
            ValueError: If used as command (not query).
        """
        if not command.is_query:
            raise ValueError("MEAS:VOLT is query only")
        if not self._output_enabled:
            return "0.000"
        if self._physics_engine is None:
            return f"{self._voltage_setpoint:.3f}"
        electrical_state = self._physics_engine.get_electrical_state()
        return f"{electrical_state.input_voltage:.3f}"
    def _handle_meas_curr(self, command: SCPICommand) -> str:
        """Handle MEAS:CURR? query.
        Args:
            command: Parsed SCPI command.
        Returns:
            Measured output current.
        Raises:
            ValueError: If used as command (not query).
        """
        if not command.is_query:
            raise ValueError("MEAS:CURR is query only")
        if not self._output_enabled:
            return "0.000"
        if self._physics_engine is None:
            return "0.000"
        electrical_state = self._physics_engine.get_electrical_state()
        # Total current is load current + quiescent current
        total_current = electrical_state.load_current + electrical_state.quiescent_current
        return f"{total_current:.3f}"
--- a/src/py_dvt_ate/tests/init.py
+++ b/src/py_dvt_ate/tests/init.py
@@ -1 +1,6 @@
-"""DVT test implementations."""
+"""DVT test implementations.
 Contains characterisation test suites organised by category:
 - thermal/ - Temperature-related tests (TempCo, etc.)
 - electrical/ - Electrical tests (load regulation, etc.)
 """
--- a/src/py_dvt_ate/tests/base.py
+++ b/src/py_dvt_ate/tests/base.py
@@ -0,0 +1,158 @@
 """Base class and utilities for DVT test implementations.
 This module provides common functionality shared across all DVT tests,
 including thermal settling helpers, measurement utilities, and statistical
 calculations.
 """
 import time
 from abc import ABC
 from collections.abc import Callable
 from py_dvt_ate.framework.context import ITest, TestContext
 class BaseDVTTest(ITest, ABC):
    """Abstract base class for DVT tests with common utilities.
    Provides helper methods for thermal settling, measurement averaging,
    and other common test patterns. All DVT tests should inherit from
    this class rather than directly from ITest.
    """
    def wait_for_temperature(
        self,
        context: TestContext,
        setpoint: float,
        timeout: float = 300.0,
        poll_interval: float = 1.0,
    ) -> bool:
        """Wait for thermal chamber to stabilise at setpoint.
        Sets the chamber temperature and waits until stable. Logs progress
        to the test logger.
        Args:
            context: Test context with instruments and logger.
            setpoint: Target temperature in degrees Celsius.
            timeout: Maximum wait time in seconds. Default 300s (5 minutes).
            poll_interval: Time between stability checks. Default 1s.
        Returns:
            True if temperature stabilised within timeout, False if timed out.
        Raises:
            ConnectionError: If instrument communication fails.
            IOError: If instrument reports error.
        """
        chamber = context.instruments.chamber
        # Set the temperature
        chamber.set_temperature(setpoint)
        context.logger.log_event(
            f"Set thermal chamber to {setpoint:.1f}°C, waiting for stability...",
            level="INFO",
        )
        # Wait for stability
        start_time = time.time()
        elapsed = 0.0
        while elapsed < timeout:
            if chamber.is_stable():
                actual = chamber.get_temperature()
                context.logger.log_event(
                    f"Chamber stable at {actual:.2f}°C "
                    f"(target {setpoint:.1f}°C) after {elapsed:.1f}s",
                    level="INFO",
                )
                return True
            time.sleep(poll_interval)
            elapsed = time.time() - start_time
        # Timeout
        actual = chamber.get_temperature()
        context.logger.log_event(
            f"Timeout waiting for stability. Chamber at {actual:.2f}°C, "
            f"target {setpoint:.1f}°C after {timeout:.1f}s",
            level="WARNING",
        )
        return False
    def measure_averaged(
        self,
        measurement_func: Callable[[], float],
        num_samples: int = 5,
        settle_time: float = 0.1,
    ) -> tuple[float, float]:
        """Take multiple measurements and return mean and standard deviation.
        Useful for reducing noise in measurements by averaging multiple samples.
        Args:
            measurement_func: Function that returns a single measurement.
            num_samples: Number of samples to average. Default 5.
            settle_time: Delay between samples in seconds. Default 0.1s.
        Returns:
            Tuple of (mean, standard_deviation).
        Raises:
            ValueError: If num_samples < 1.
            Exception: If measurement_func raises an exception.
        """
        if num_samples < 1:
            raise ValueError("num_samples must be at least 1")
        samples: list[float] = []
        for _ in range(num_samples):
            if settle_time > 0 and len(samples) > 0:
                time.sleep(settle_time)
            samples.append(measurement_func())
        mean = sum(samples) / len(samples)
        if len(samples) == 1:
            std_dev = 0.0
        else:
            variance = sum((x - mean) ** 2 for x in samples) / (len(samples) - 1)
            std_dev = variance ** 0.5
        return mean, std_dev
    def thermal_settle(
        self,
        context: TestContext,
        additional_settle_time: float = 5.0,
    ) -> None:
        """Wait for additional thermal settling after chamber reports stable.
        After the chamber reports stable temperature, this adds additional
        settling time to ensure the DUT junction temperature has also stabilised.
        This is important for measurements sensitive to self-heating effects.
        Args:
            context: Test context with logger.
            additional_settle_time: Extra settling time in seconds. Default 5s.
        """
        if additional_settle_time > 0:
            context.logger.log_event(
                f"Additional thermal settling for {additional_settle_time:.1f}s...",
                level="INFO",
            )
            time.sleep(additional_settle_time)
    def delay(self, seconds: float, message: str | None = None) -> None:
        """Sleep for specified duration.
        Simple utility for adding delays in test sequences.
        Args:
            seconds: Delay duration in seconds.
            message: Optional message describing reason for delay.
        """
        if message:
            # Could log this if needed
            pass
        time.sleep(seconds)
--- a/src/py_dvt_ate/tests/electrical/init.py
+++ b/src/py_dvt_ate/tests/electrical/init.py
@@ -0,0 +1,5 @@
 """Electrical characterisation tests.
 Tests for electrical performance including load regulation,
 line regulation, and output accuracy.
 """
--- a/src/py_dvt_ate/tests/thermal/init.py
+++ b/src/py_dvt_ate/tests/thermal/init.py
@@ -0,0 +1,5 @@
 """Thermal characterisation tests.
 Tests related to temperature behaviour including temperature
 coefficient (TempCo) measurements and thermal stability.
 """
--- a/src/py_dvt_ate/tests/thermal/tempco.py
+++ b/src/py_dvt_ate/tests/thermal/tempco.py
@@ -0,0 +1,243 @@
 """Temperature Coefficient (TempCo) characterisation test.
 This test characterises the output voltage temperature coefficient by
 sweeping the chamber temperature and measuring output voltage at each point.
 The TempCo is calculated from the linear regression slope and expressed
 in parts per million per degree Celsius (ppm/°C).
 """
 from py_dvt_ate.data.models import TestStatus
 from py_dvt_ate.framework.context import TestContext
 from py_dvt_ate.tests.base import BaseDVTTest
 class TempCoTest(BaseDVTTest):
    """Temperature coefficient characterisation test.
    Measures how output voltage varies with temperature. This is a critical
    parameter for voltage regulators, as it indicates stability across
    the operating temperature range.
    Test Procedure:
        1. Configure DUT supply voltage and load current
        2. Sweep chamber temperature from min to max
        3. At each temperature point:
           - Wait for thermal stability
           - Measure output voltage (averaged)
           - Log measurement with conditions
        4. Calculate TempCo from linear regression
        5. Evaluate against specification limits
    Configuration:
        temperatures: List of temperature points (°C). Default: [-40, -20, 0, 25, 50, 85]
        input_voltage: DUT input voltage (V). Default: 5.0
        load_current: DUT load current (A). Default: 0.1
        settle_time: Additional settling time at each temp (s). Default: 5.0
        num_samples: Number of measurements to average per point. Default: 5
        tempco_limit: Maximum allowed TempCo magnitude (ppm/°C). Default: ±50.0
    """
    @property
    def name(self) -> str:
        """Return test identifier."""
        return "tempco"
    @property
    def description(self) -> str:
        """Return test description."""
        return "Output voltage temperature coefficient"
    def execute(self, context: TestContext) -> TestStatus:
        """Execute TempCo characterisation test.
        Args:
            context: Test context with instruments, logger, and configuration.
        Returns:
            PASSED if TempCo is within limits, FAILED otherwise.
            ERROR if a critical failure occurs.
        """
        try:
            # Get configuration
            config = context.config
            temperatures = config.get("temperatures", [-40.0, -20.0, 0.0, 25.0, 50.0, 85.0])
            input_voltage = config.get("input_voltage", 5.0)
            load_current = config.get("load_current", 0.1)
            settle_time = config.get("settle_time", 5.0)
            num_samples = config.get("num_samples", 5)
            tempco_limit = config.get("tempco_limit", 50.0)
            context.logger.log_event(
                f"Starting TempCo test: {len(temperatures)} temperature points, "
                f"Vin={input_voltage}V, Iload={load_current}A",
                level="INFO",
            )
            # Configure DUT power
            context.logger.log_event(
                f"Configuring PSU: Vin={input_voltage}V, Ilimit={load_current + 0.5}A",
                level="INFO",
            )
            psu = context.instruments.psu
            psu.set_voltage(1, input_voltage)
            psu.set_current_limit(1, load_current + 0.5)  # Add headroom
            psu.enable_output(1, True)
            # Storage for measurements
            temp_points: list[float] = []
            vout_points: list[float] = []
            # Temperature sweep
            for temp_setpoint in temperatures:
                context.logger.log_event(
                    f"Temperature point: {temp_setpoint}°C",
                    level="INFO",
                )
                # Wait for thermal stability
                stable = self.wait_for_temperature(
                    context,
                    temp_setpoint,
                    timeout=300.0,
                )
                if not stable:
                    context.logger.log_event(
                        f"Warning: Temperature did not stabilise at {temp_setpoint}°C",
                        level="WARNING",
                    )
                # Additional settling for DUT junction temperature
                self.thermal_settle(context, settle_time)
                # Measure output voltage (averaged)
                actual_temp = context.instruments.chamber.get_temperature()
                def measure_vout() -> float:
                    return context.instruments.dmm.measure_dc_voltage()
                vout_mean, vout_std = self.measure_averaged(
                    measure_vout,
                    num_samples=num_samples,
                )
                # Log individual measurement
                context.logger.log_measurement(
                    parameter="v_out",
                    value=vout_mean,
                    unit="V",
                    conditions={
                        "temperature": actual_temp,
                        "input_voltage": input_voltage,
                        "load_current": load_current,
                    },
                )
                context.logger.log_event(
                    f"Measured Vout = {vout_mean:.6f}V ± {vout_std * 1e6:.1f}μV "
                    f"at T={actual_temp:.2f}°C",
                    level="INFO",
                )
                # Store for TempCo calculation
                temp_points.append(actual_temp)
                vout_points.append(vout_mean)
            # Calculate TempCo from linear regression
            tempco_ppm = self._calculate_tempco(temp_points, vout_points)
            context.logger.log_event(
                f"Calculated TempCo = {tempco_ppm:.2f} ppm/°C",
                level="INFO",
            )
            # Log result with limits
            context.logger.log_result(
                parameter="temp_co",
                value=tempco_ppm,
                unit="ppm/°C",
                lower_limit=-abs(tempco_limit),
                upper_limit=abs(tempco_limit),
            )
            # Evaluate pass/fail
            passed = abs(tempco_ppm) <= tempco_limit
            if passed:
                context.logger.log_event(
                    f"TempCo test PASSED: {tempco_ppm:.2f} ppm/°C within ±{tempco_limit} ppm/°C",
                    level="INFO",
                )
                return TestStatus.PASSED
            else:
                context.logger.log_event(
                    f"TempCo test FAILED: {tempco_ppm:.2f} ppm/°C exceeds ±{tempco_limit} ppm/°C",
                    level="ERROR",
                )
                return TestStatus.FAILED
        except Exception as e:
            context.logger.log_event(
                f"TempCo test ERROR: {e!s}",
                level="ERROR",
            )
            return TestStatus.ERROR
        finally:
            # Cleanup: disable PSU output
            try:
                context.instruments.psu.enable_output(1, False)
                context.logger.log_event("PSU output disabled", level="INFO")
            except Exception:
                pass  # Best effort cleanup
    def _calculate_tempco(
        self,
        temperatures: list[float],
        voltages: list[float],
    ) -> float:
        """Calculate temperature coefficient from measurements.
        Uses linear regression to find the slope (dV/dT), then converts
        to ppm/°C relative to the nominal voltage (voltage at median temperature).
        Args:
            temperatures: Temperature measurements in °C.
            voltages: Output voltage measurements in V.
        Returns:
            Temperature coefficient in ppm/°C.
        Raises:
            ValueError: If insufficient data points.
        """
        if len(temperatures) < 2 or len(temperatures) != len(voltages):
            raise ValueError("Need at least 2 matching temperature-voltage pairs")
        n = len(temperatures)
        # Linear regression: V = a + b*T
        # We want slope b = dV/dT
        mean_t = sum(temperatures) / n
        mean_v = sum(voltages) / n
        # Covariance and variance
        cov = sum(
            (t - mean_t) * (v - mean_v)
            for t, v in zip(temperatures, voltages, strict=True)
        )
        var_t = sum((t - mean_t) ** 2 for t in temperatures)
        if var_t == 0:
            raise ValueError("Temperature variance is zero (all temps identical)")
        slope = cov / var_t  # dV/dT in V/°C
        # Find nominal voltage (voltage at median temperature)
        sorted_pairs = sorted(zip(temperatures, voltages, strict=True))
        mid_idx = len(sorted_pairs) // 2
        v_nominal = sorted_pairs[mid_idx][1]
        # Convert to ppm/°C: (dV/dT) / V_nom * 10^6
        tempco_ppm = (slope / v_nominal) * 1e6
        return tempco_ppm
--- a/src/py_dvt_ate/transport/init.py
+++ b/src/py_dvt_ate/transport/init.py
@@ -1 +0,0 @@
 """Communication layer."""
--- a/tests/conftest.py
+++ b/tests/conftest.py
@@ -1 +1,8 @@
 """pytest fixtures for py_dvt_ate tests."""
 import pytest
 def pytest_configure(config: pytest.Config) -> None:
    """Configure pytest markers."""
    config.addinivalue_line("markers", "asyncio: mark test as async")
--- a/tests/integration/init.py
+++ b/tests/integration/init.py
@@ -0,0 +1 @@
 """Integration tests for py_dvt_ate."""
--- a/tests/integration/conftest.py
+++ b/tests/integration/conftest.py
@@ -0,0 +1 @@
 """Configuration for integration tests."""
--- a/tests/integration/test_tcp_server.py
+++ b/tests/integration/test_tcp_server.py
@@ -0,0 +1,272 @@
 """Integration tests for TCP server.
 Tests the InstrumentServer and SimulationServer with actual TCP connections.
 """
 from __future__ import annotations
 import asyncio
 import pytest
 from py_dvt_ate.instruments.transport import InstrumentServer
 from py_dvt_ate.simulation.physics.engine import PhysicsEngine
 from py_dvt_ate.simulation.server import ServerConfig, SimulationServer
 from py_dvt_ate.simulation.virtual.chamber import ThermalChamberSim
@pytest.mark.asyncio(loop_scope="function")
 class TestInstrumentServer:
    """Tests for InstrumentServer TCP functionality."""
    @pytest.fixture
    def physics_engine(self) -> PhysicsEngine:
        """Create a physics engine for testing."""
        return PhysicsEngine(update_rate_hz=100.0)
    @pytest.fixture
    def server(self, physics_engine: PhysicsEngine) -> InstrumentServer:
        """Create an instrument server with a thermal chamber."""
        server = InstrumentServer(host="127.0.0.1")
        chamber = ThermalChamberSim(physics_engine)
        server.register_instrument(15000, chamber)
        return server
    async def test_server_start_stop(self, server: InstrumentServer) -> None:
        """Test server can start and stop."""
        assert not server.is_running
        await server.start()
        assert server.is_running
        await server.stop()
        assert not server.is_running
    async def test_client_connection(self, server: InstrumentServer) -> None:
        """Test client can connect and send command."""
        await server.start()
        try:
            reader, writer = await asyncio.open_connection("127.0.0.1", 15000)
            # Send *IDN? query
            writer.write(b"*IDN?\n")
            await writer.drain()
            # Read response
            response = await asyncio.wait_for(reader.readline(), timeout=2.0)
            assert b"PyDVTATE" in response
            assert b"TC-SIM-001" in response
            writer.close()
            await writer.wait_closed()
        finally:
            await server.stop()
    async def test_multiple_commands(self, server: InstrumentServer) -> None:
        """Test sending multiple commands in sequence."""
        await server.start()
        try:
            reader, writer = await asyncio.open_connection("127.0.0.1", 15000)
            # Set temperature setpoint
            writer.write(b"TEMP:SETPOINT 85.0\n")
            await writer.drain()
            # Query setpoint
            writer.write(b"TEMP:SETPOINT?\n")
            await writer.drain()
            response = await asyncio.wait_for(reader.readline(), timeout=2.0)
            assert b"85.00" in response
            # Query actual temperature
            writer.write(b"TEMP:ACTUAL?\n")
            await writer.drain()
            response = await asyncio.wait_for(reader.readline(), timeout=2.0)
            # Should return a valid float
            temp = float(response.decode().strip())
            assert -50 <= temp <= 200
            writer.close()
            await writer.wait_closed()
        finally:
            await server.stop()
    async def test_concurrent_connections(
        self, physics_engine: PhysicsEngine
    ) -> None:
        """Test multiple concurrent client connections."""
        server = InstrumentServer(host="127.0.0.1")
        chamber = ThermalChamberSim(physics_engine)
        server.register_instrument(15001, chamber)
        await server.start()
        try:
            # Connect two clients simultaneously
            reader1, writer1 = await asyncio.open_connection("127.0.0.1", 15001)
            reader2, writer2 = await asyncio.open_connection("127.0.0.1", 15001)
            # Send command from client 1
            writer1.write(b"*IDN?\n")
            await writer1.drain()
            response1 = await asyncio.wait_for(reader1.readline(), timeout=2.0)
            # Send command from client 2
            writer2.write(b"*IDN?\n")
            await writer2.drain()
            response2 = await asyncio.wait_for(reader2.readline(), timeout=2.0)
            # Both should get valid responses
            assert b"TC-SIM-001" in response1
            assert b"TC-SIM-001" in response2
            writer1.close()
            writer2.close()
            await writer1.wait_closed()
            await writer2.wait_closed()
        finally:
            await server.stop()
@pytest.mark.asyncio(loop_scope="function")
 class TestSimulationServer:
    """Tests for complete SimulationServer."""
    async def test_simulation_server_start_stop(self) -> None:
        """Test simulation server lifecycle."""
        config = ServerConfig(
            host="127.0.0.1",
            chamber_port=16000,
            psu_port=16001,
            dmm_port=16002,
            physics_rate_hz=100.0,
        )
        server = SimulationServer(config)
        assert not server.is_running
        await server.start()
        assert server.is_running
        assert server.physics_engine is not None
        await server.stop()
        assert not server.is_running
    async def test_all_instruments_accessible(self) -> None:
        """Test all three instruments are accessible over TCP."""
        config = ServerConfig(
            host="127.0.0.1",
            chamber_port=16100,
            psu_port=16101,
            dmm_port=16102,
        )
        server = SimulationServer(config)
        await server.start()
        try:
            # Test thermal chamber
            r, w = await asyncio.open_connection("127.0.0.1", 16100)
            w.write(b"*IDN?\n")
            await w.drain()
            resp = await asyncio.wait_for(r.readline(), timeout=2.0)
            assert b"TC-SIM-001" in resp
            w.close()
            await w.wait_closed()
            # Test power supply
            r, w = await asyncio.open_connection("127.0.0.1", 16101)
            w.write(b"*IDN?\n")
            await w.drain()
            resp = await asyncio.wait_for(r.readline(), timeout=2.0)
            assert b"PS-SIM-001" in resp
            w.close()
            await w.wait_closed()
            # Test multimeter
            r, w = await asyncio.open_connection("127.0.0.1", 16102)
            w.write(b"*IDN?\n")
            await w.drain()
            resp = await asyncio.wait_for(r.readline(), timeout=2.0)
            assert b"DMM-SIM-001" in resp
            w.close()
            await w.wait_closed()
        finally:
            await server.stop()
    async def test_physics_engine_integration(self) -> None:
        """Test instruments share physics engine state."""
        config = ServerConfig(
            host="127.0.0.1",
            chamber_port=16200,
            psu_port=16201,
            dmm_port=16202,
        )
        server = SimulationServer(config)
        await server.start()
        try:
            # Connect to power supply and enable output
            psu_r, psu_w = await asyncio.open_connection("127.0.0.1", 16201)
            psu_w.write(b"VOLT 5.0\n")
            await psu_w.drain()
            psu_w.write(b"OUTP ON\n")
            await psu_w.drain()
            # Run a few physics steps
            await asyncio.sleep(0.1)
            # Query voltage from power supply
            psu_w.write(b"MEAS:VOLT?\n")
            await psu_w.drain()
            psu_resp = await asyncio.wait_for(psu_r.readline(), timeout=2.0)
            psu_voltage = float(psu_resp.decode().strip())
            # Connect to DMM and measure DUT output
            dmm_r, dmm_w = await asyncio.open_connection("127.0.0.1", 16202)
            dmm_w.write(b"MEAS:VOLT:DC?\n")
            await dmm_w.drain()
            dmm_resp = await asyncio.wait_for(dmm_r.readline(), timeout=2.0)
            dmm_voltage = float(dmm_resp.decode().strip())
            # PSU should show input voltage (5V)
            assert 4.9 <= psu_voltage <= 5.1
            # DMM should show DUT output voltage (LDO regulated ~3.3V)
            assert 3.0 <= dmm_voltage <= 3.5
            psu_w.close()
            dmm_w.close()
            await psu_w.wait_closed()
            await dmm_w.wait_closed()
        finally:
            await server.stop()
    async def test_error_handling(self) -> None:
        """Test invalid commands return errors."""
        config = ServerConfig(
            host="127.0.0.1",
            chamber_port=16300,
            psu_port=16301,
            dmm_port=16302,
        )
        server = SimulationServer(config)
        await server.start()
        try:
            r, w = await asyncio.open_connection("127.0.0.1", 16300)
            # Send invalid command
            w.write(b"INVALID:COMMAND\n")
            await w.drain()
            resp = await asyncio.wait_for(r.readline(), timeout=2.0)
            assert b"ERROR" in resp
            w.close()
            await w.wait_closed()
        finally:
            await server.stop()
--- a/tests/integration/test_tempco.py
+++ b/tests/integration/test_tempco.py
@@ -0,0 +1,267 @@
 """Integration tests for TempCo characterisation test.
 Full end-to-end test of the TempCo test with simulated instruments.
 """
 from __future__ import annotations
 from pathlib import Path
 import pytest
 from py_dvt_ate.data.models import TestStatus
 from py_dvt_ate.data.repository import SQLiteRepository
 from py_dvt_ate.framework.context import TestContext
 from py_dvt_ate.framework.logger import TestLogger
 from py_dvt_ate.instruments.factory import InstrumentConfig, InstrumentFactory
 from py_dvt_ate.simulation.server import ServerConfig, SimulationServer
 from py_dvt_ate.tests.thermal.tempco import TempCoTest
@pytest.mark.asyncio(loop_scope="function")
 class TestTempCoIntegration:
    """Integration tests for TempCo test with simulator."""
    async def test_tempco_runs_successfully(self, tmp_path: Path) -> None:
        """Test TempCo test runs end-to-end with simulator."""
        # Start simulation server
        server_config = ServerConfig(
            host="127.0.0.1",
            chamber_port=17000,
            psu_port=17001,
            dmm_port=17002,
            physics_rate_hz=100.0,
        )
        server = SimulationServer(server_config)
        await server.start()
        try:
            # Create instrument set connected to simulator
            instrument_config = InstrumentConfig(
                backend="simulator",
                simulator_host="127.0.0.1",
                chamber_port=17000,
                psu_port=17001,
                dmm_port=17002,
            )
            instruments = InstrumentFactory.create(instrument_config)
            # Connect to instruments
            instruments.chamber.connect()
            instruments.psu.connect()
            instruments.dmm.connect()
            # Configure instruments
            instruments.chamber.set_ramp_rate(10.0)  # Fast ramp for testing
            instruments.psu.enable_output(1, False)  # Ensure off initially
            # Create test repository
            db_path = tmp_path / "test.db"
            repository = SQLiteRepository(db_path)
            # Create test run
            run_id = repository.create_run(
                test_name="tempco",
                config={
                    "temperatures": [0.0, 25.0, 50.0],  # Reduced for faster test
                    "input_voltage": 5.0,
                    "load_current": 0.1,
                    "settle_time": 0.5,  # Reduced for faster test
                    "num_samples": 3,  # Reduced for faster test
                    "tempco_limit": 100.0,  # Relaxed for testing
                },
                description="Integration test of TempCo",
            )
            # Create test logger
            logger = TestLogger(run_id, repository)
            # Create test context
            context = TestContext(
                run_id=run_id,
                instruments=instruments,
                logger=logger,
                config={
                    "temperatures": [0.0, 25.0, 50.0],
                    "input_voltage": 5.0,
                    "load_current": 0.1,
                    "settle_time": 0.5,
                    "num_samples": 3,
                    "tempco_limit": 100.0,
                },
            )
            # Create and execute test
            test = TempCoTest()
            assert test.name == "tempco"
            assert test.description == "Output voltage temperature coefficient"
            # Run test (this is synchronous, but simulation runs async in background)
            status = test.execute(context)
            # Verify test completed
            assert status in (TestStatus.PASSED, TestStatus.FAILED)
            # Flush logger to ensure all data is written
            logger.flush()
            # Update run status
            repository.complete_run(run_id, status)
            # Verify results were logged
            results = repository.get_results(run_id)
            assert len(results) > 0
            # Find TempCo result
            tempco_result = next(r for r in results if r.parameter == "temp_co")
            assert tempco_result is not None
            assert tempco_result.unit == "ppm/°C"
            assert tempco_result.lower_limit == -100.0
            assert tempco_result.upper_limit == 100.0
            # Verify measurements were logged
            df = repository.get_measurements_dataframe(run_id)
            assert df is not None
            assert len(df) >= 3  # At least 3 temperature points
            # Verify v_out measurements exist
            vout_measurements = df[df["parameter"] == "v_out"]
            assert len(vout_measurements) >= 3
            # Verify temperature conditions were logged
            assert "temperature" in df.columns
            temps_recorded = vout_measurements["temperature"].unique()
            assert len(temps_recorded) >= 3
        finally:
            await server.stop()
    async def test_tempco_with_minimal_config(self, tmp_path: Path) -> None:
        """Test TempCo uses default configuration when not specified."""
        # Start simulation server
        server_config = ServerConfig(
            host="127.0.0.1",
            chamber_port=17100,
            psu_port=17101,
            dmm_port=17102,
        )
        server = SimulationServer(server_config)
        await server.start()
        try:
            # Create instrument set
            instrument_config = InstrumentConfig(
                backend="simulator",
                simulator_host="127.0.0.1",
                chamber_port=17100,
                psu_port=17101,
                dmm_port=17102,
            )
            instruments = InstrumentFactory.create(instrument_config)
            # Connect to instruments
            instruments.chamber.connect()
            instruments.psu.connect()
            instruments.dmm.connect()
            # Create repository
            db_path = tmp_path / "test_minimal.db"
            repository = SQLiteRepository(db_path)
            run_id = repository.create_run(
                test_name="tempco",
                config={},  # Empty config - should use defaults
            )
            # Create logger and context with minimal config
            logger = TestLogger(run_id, repository)
            context = TestContext(
                run_id=run_id,
                instruments=instruments,
                logger=logger,
                config={
                    # Override temperatures for faster test
                    "temperatures": [25.0, 50.0],
                    "settle_time": 0.2,
                    "num_samples": 2,
                },
            )
            # Execute test
            test = TempCoTest()
            status = test.execute(context)
            # Should complete without error
            assert status in (TestStatus.PASSED, TestStatus.FAILED, TestStatus.ERROR)
            logger.flush()
            repository.complete_run(run_id, status)
            # Verify some data was logged
            results = repository.get_results(run_id)
            assert len(results) >= 1
        finally:
            await server.stop()
    async def test_tempco_handles_errors_gracefully(self, tmp_path: Path) -> None:
        """Test TempCo returns ERROR status when instruments fail."""
        # Start simulation server
        server_config = ServerConfig(
            host="127.0.0.1",
            chamber_port=17200,
            psu_port=17201,
            dmm_port=17202,
        )
        server = SimulationServer(server_config)
        await server.start()
        try:
            # Create instrument set
            instrument_config = InstrumentConfig(
                backend="simulator",
                simulator_host="127.0.0.1",
                chamber_port=17200,
                psu_port=17201,
                dmm_port=17202,
            )
            instruments = InstrumentFactory.create(instrument_config)
            # Connect to instruments
            instruments.chamber.connect()
            instruments.psu.connect()
            instruments.dmm.connect()
            # Create repository
            db_path = tmp_path / "test_error.db"
            repository = SQLiteRepository(db_path)
            run_id = repository.create_run(test_name="tempco", config={})
            # Create logger and context
            logger = TestLogger(run_id, repository)
            context = TestContext(
                run_id=run_id,
                instruments=instruments,
                logger=logger,
                config={
                    "temperatures": [],  # Invalid: empty temperature list
                    "settle_time": 0.1,
                },
            )
            # Execute test
            test = TempCoTest()
            # Should handle gracefully (may return FAILED or ERROR)
            # The test should not raise an unhandled exception
            try:
                status = test.execute(context)
                # If it completes, it should indicate an error or failure
                assert status in (TestStatus.ERROR, TestStatus.FAILED)
            except Exception:
                # Or it might raise, which we also consider handled
                pass
            logger.flush()
        finally:
            await server.stop()
--- a/tests/unit/test_config.py
+++ b/tests/unit/test_config.py
@@ -0,0 +1,266 @@
 """Tests for configuration loading and validation."""
 from pathlib import Path
 from typing import Any
 import pytest
 import yaml
 from pydantic import ValidationError
 from py_dvt_ate.app.config import (
    APIConfig,
    AppConfig,
    ChamberConfig,
    DashboardConfig,
    DataConfig,
    DUTConfig,
    DUTParameters,
    InstrumentsConfig,
    LoggingConfig,
    PhysicsConfig,
    PyVISAConfig,
    SimulatorConfig,
    ThermalConfig,
    load_config,
 )
 def test_default_config_values() -> None:
    """Test that default configuration values are correct."""
    config = AppConfig()
    assert config.instruments.backend == "simulator"
    assert config.instruments.simulator.host == "localhost"
    assert config.instruments.simulator.thermal_chamber_port == 5001
    assert config.physics.update_rate_hz == 100.0
    assert config.physics.thermal.chamber_time_constant_s == 30.0
    assert config.physics.thermal.theta_jc == 15.0
    assert config.dut.model == "ldo"
    assert config.dut.parameters.nominal_output_voltage == 3.3
    assert config.dut.parameters.tempco_ppm_per_c == 50.0
    assert config.data.database_path == "./data/py_dvt_ate.db"
    assert config.logging.level == "INFO"
    assert config.dashboard.enabled is True
    assert config.api.enabled is False
 def test_load_config_with_defaults_only() -> None:
    """Test loading config without a file uses defaults."""
    config = load_config(None)
    assert config.instruments.backend == "simulator"
    assert config.physics.update_rate_hz == 100.0
 def test_load_config_from_file(tmp_path: Path) -> None:
    """Test loading configuration from YAML file."""
    config_file = tmp_path / "test_config.yaml"
    config_data = {
        "instruments": {"backend": "pyvisa"},
        "physics": {"update_rate_hz": 50.0},
        "dut": {"model": "custom_ldo"},
    }
    with config_file.open("w") as f:
        yaml.dump(config_data, f)
    config = load_config(config_file)
    assert config.instruments.backend == "pyvisa"
    assert config.physics.update_rate_hz == 50.0
    assert config.dut.model == "custom_ldo"
    # Defaults still apply
    assert config.instruments.simulator.host == "localhost"
 def test_load_config_partial_override(tmp_path: Path) -> None:
    """Test that partial config overrides work correctly."""
    config_file = tmp_path / "partial.yaml"
    config_data = {
        "physics": {
            "thermal": {
                "theta_jc": 20.0,
                # Other thermal params should use defaults
            }
        }
    }
    with config_file.open("w") as f:
        yaml.dump(config_data, f)
    config = load_config(config_file)
    # Overridden value
    assert config.physics.thermal.theta_jc == 20.0
    # Default values
    assert config.physics.thermal.theta_ca == 5.0
    assert config.physics.thermal.chamber_time_constant_s == 30.0
 def test_load_config_missing_file() -> None:
    """Test that loading from missing file raises FileNotFoundError."""
    with pytest.raises(FileNotFoundError, match="Configuration file not found"):
        load_config("nonexistent.yaml")
 def test_load_config_invalid_yaml(tmp_path: Path) -> None:
    """Test that malformed YAML raises an error."""
    config_file = tmp_path / "invalid.yaml"
    config_file.write_text("invalid: yaml: content: [\n")
    with pytest.raises(yaml.YAMLError):
        load_config(config_file)
 def test_load_config_validation_error(tmp_path: Path) -> None:
    """Test that invalid configuration raises ValidationError."""
    config_file = tmp_path / "invalid_config.yaml"
    config_data = {
        "instruments": {"backend": "invalid_backend"},  # Not in Literal["simulator", "pyvisa"]
    }
    with config_file.open("w") as f:
        yaml.dump(config_data, f)
    with pytest.raises(ValidationError):
        load_config(config_file)
 def test_env_override_simple(tmp_path: Path, monkeypatch: pytest.MonkeyPatch) -> None:
    """Test environment variable override for simple values."""
    config_file = tmp_path / "config.yaml"
    config_data: dict[str, Any] = {}
    with config_file.open("w") as f:
        yaml.dump(config_data, f)
    monkeypatch.setenv("PYDVTATE__INSTRUMENTS__BACKEND", "pyvisa")
    monkeypatch.setenv("PYDVTATE__PHYSICS__UPDATE_RATE_HZ", "200.0")
    config = load_config(config_file)
    assert config.instruments.backend == "pyvisa"
    assert config.physics.update_rate_hz == 200.0
 def test_env_override_nested(tmp_path: Path, monkeypatch: pytest.MonkeyPatch) -> None:
    """Test environment variable override for nested values."""
    config_file = tmp_path / "config.yaml"
    config_data: dict[str, Any] = {}
    with config_file.open("w") as f:
        yaml.dump(config_data, f)
    monkeypatch.setenv("PYDVTATE__INSTRUMENTS__SIMULATOR__HOST", "192.168.1.100")
    monkeypatch.setenv("PYDVTATE__INSTRUMENTS__SIMULATOR__THERMAL_CHAMBER_PORT", "6001")
    monkeypatch.setenv("PYDVTATE__PHYSICS__THERMAL__THETA_JC", "25.0")
    config = load_config(config_file)
    assert config.instruments.simulator.host == "192.168.1.100"
    assert config.instruments.simulator.thermal_chamber_port == 6001
    assert config.physics.thermal.theta_jc == 25.0
 def test_env_override_types(tmp_path: Path, monkeypatch: pytest.MonkeyPatch) -> None:
    """Test that environment variables are parsed to correct types."""
    config_file = tmp_path / "config.yaml"
    config_data: dict[str, Any] = {}
    with config_file.open("w") as f:
        yaml.dump(config_data, f)
    monkeypatch.setenv("PYDVTATE__DASHBOARD__ENABLED", "false")  # bool
    monkeypatch.setenv("PYDVTATE__DASHBOARD__PORT", "9000")  # int
    monkeypatch.setenv("PYDVTATE__PHYSICS__UPDATE_RATE_HZ", "75.5")  # float
    config = load_config(config_file)
    assert config.dashboard.enabled is False
    assert config.dashboard.port == 9000
    assert config.physics.update_rate_hz == 75.5
 def test_env_override_precedence(tmp_path: Path, monkeypatch: pytest.MonkeyPatch) -> None:
    """Test that environment variables override file values."""
    config_file = tmp_path / "config.yaml"
    config_data = {"physics": {"update_rate_hz": 50.0}}
    with config_file.open("w") as f:
        yaml.dump(config_data, f)
    monkeypatch.setenv("PYDVTATE__PHYSICS__UPDATE_RATE_HZ", "150.0")
    config = load_config(config_file)
    # Environment variable should win
    assert config.physics.update_rate_hz == 150.0
 def test_env_variables_ignored_without_prefix(
    tmp_path: Path, monkeypatch: pytest.MonkeyPatch
 ) -> None:
    """Test that environment variables without prefix are ignored."""
    config_file = tmp_path / "config.yaml"
    config_data: dict[str, Any] = {}
    with config_file.open("w") as f:
        yaml.dump(config_data, f)
    # These should be ignored
    monkeypatch.setenv("BACKEND", "pyvisa")
    monkeypatch.setenv("UPDATE_RATE_HZ", "200.0")
    config = load_config(config_file)
    # Should use defaults
    assert config.instruments.backend == "simulator"
    assert config.physics.update_rate_hz == 100.0
 def test_simulator_config_defaults() -> None:
    """Test SimulatorConfig default values."""
    config = SimulatorConfig()
    assert config.host == "localhost"
    assert config.thermal_chamber_port == 5001
    assert config.power_supply_port == 5002
    assert config.multimeter_port == 5003
 def test_pyvisa_config_defaults() -> None:
    """Test PyVISAConfig default values."""
    config = PyVISAConfig()
    assert config.thermal_chamber is None
    assert config.power_supply is None
    assert config.multimeter is None
 def test_complete_config_structure() -> None:
    """Test that all config sections can be instantiated."""
    config = AppConfig(
        instruments=InstrumentsConfig(
            backend="pyvisa",
            simulator=SimulatorConfig(host="192.168.1.1"),
            pyvisa=PyVISAConfig(thermal_chamber="TCPIP::192.168.1.10::INSTR"),
        ),
        physics=PhysicsConfig(
            update_rate_hz=50.0,
            thermal=ThermalConfig(theta_jc=20.0),
            chamber=ChamberConfig(ramp_rate_c_per_min=5.0),
        ),
        dut=DUTConfig(
            model="custom", parameters=DUTParameters(nominal_output_voltage=5.0)
        ),
        data=DataConfig(database_path="/tmp/test.db"),
        logging=LoggingConfig(level="DEBUG"),
        dashboard=DashboardConfig(enabled=False),
        api=APIConfig(enabled=True, port=9000),
    )
    assert config.instruments.backend == "pyvisa"
    assert config.physics.update_rate_hz == 50.0
    assert config.dut.parameters.nominal_output_voltage == 5.0
    assert config.api.port == 9000
--- a/tests/unit/test_drivers.py
+++ b/tests/unit/test_drivers.py
@@ -0,0 +1,346 @@
 """Unit tests for instrument drivers.
 Tests SCPI command formatting and driver functionality using mock transports.
 """
 from unittest.mock import MagicMock
 import pytest
 from py_dvt_ate.instruments.drivers.base import BaseDriver
 from py_dvt_ate.instruments.drivers.chamber import ThermalChamberDriver
 from py_dvt_ate.instruments.drivers.multimeter import MultimeterDriver
 from py_dvt_ate.instruments.drivers.power_supply import PowerSupplyDriver
@pytest.fixture
 def mock_transport():
    """Create a mock transport for testing."""
    transport = MagicMock()
    transport.is_connected = True
    return transport
 class TestBaseDriver:
    """Tests for BaseDriver base class."""
    def test_connect(self, mock_transport):
        """Test connection establishment."""
        driver = BaseDriver(mock_transport)
        driver.connect()
        mock_transport.connect.assert_called_once()
    def test_disconnect(self, mock_transport):
        """Test disconnection."""
        driver = BaseDriver(mock_transport)
        driver.disconnect()
        mock_transport.disconnect.assert_called_once()
    def test_is_connected(self, mock_transport):
        """Test connection status check."""
        driver = BaseDriver(mock_transport)
        assert driver.is_connected is True
    def test_write(self, mock_transport):
        """Test SCPI command write."""
        driver = BaseDriver(mock_transport)
        driver.write("VOLT 3.3")
        mock_transport.write.assert_called_once_with("VOLT 3.3")
    def test_query(self, mock_transport):
        """Test SCPI query."""
        mock_transport.query.return_value = "3.300"
        driver = BaseDriver(mock_transport)
        result = driver.query("VOLT?")
        assert result == "3.300"
        mock_transport.query.assert_called_once_with("VOLT?", None)
    def test_query_float(self, mock_transport):
        """Test SCPI query with float parsing."""
        mock_transport.query.return_value = "3.300"
        driver = BaseDriver(mock_transport)
        result = driver.query_float("VOLT?")
        assert result == 3.3
        assert isinstance(result, float)
    def test_query_float_invalid(self, mock_transport):
        """Test SCPI query with invalid float response."""
        mock_transport.query.return_value = "INVALID"
        driver = BaseDriver(mock_transport)
        with pytest.raises(ValueError, match="Cannot parse 'INVALID' as float"):
            driver.query_float("VOLT?")
    def test_query_int(self, mock_transport):
        """Test SCPI query with integer parsing."""
        mock_transport.query.return_value = "42"
        driver = BaseDriver(mock_transport)
        result = driver.query_int("COUNT?")
        assert result == 42
        assert isinstance(result, int)
    def test_query_int_invalid(self, mock_transport):
        """Test SCPI query with invalid integer response."""
        mock_transport.query.return_value = "3.14"
        driver = BaseDriver(mock_transport)
        with pytest.raises(ValueError, match="Cannot parse '3.14' as int"):
            driver.query_int("COUNT?")
    def test_query_bool_true_variants(self, mock_transport):
        """Test SCPI query with boolean parsing - true variants."""
        driver = BaseDriver(mock_transport)
        for value in ["1", "ON", "TRUE", "on", "true"]:
            mock_transport.query.return_value = value
            result = driver.query_bool("OUTP?")
            assert result is True
    def test_query_bool_false_variants(self, mock_transport):
        """Test SCPI query with boolean parsing - false variants."""
        driver = BaseDriver(mock_transport)
        for value in ["0", "OFF", "FALSE", "off", "false"]:
            mock_transport.query.return_value = value
            result = driver.query_bool("OUTP?")
            assert result is False
    def test_query_bool_invalid(self, mock_transport):
        """Test SCPI query with invalid boolean response."""
        mock_transport.query.return_value = "MAYBE"
        driver = BaseDriver(mock_transport)
        with pytest.raises(ValueError, match="Cannot parse 'MAYBE' as bool"):
            driver.query_bool("OUTP?")
    def test_identify(self, mock_transport):
        """Test instrument identification query."""
        mock_transport.query.return_value = "Manufacturer,Model,SN123,1.0.0"
        driver = BaseDriver(mock_transport)
        result = driver.identify()
        assert result == "Manufacturer,Model,SN123,1.0.0"
        mock_transport.query.assert_called_once_with("*IDN?", None)
    def test_reset(self, mock_transport):
        """Test instrument reset command."""
        driver = BaseDriver(mock_transport)
        driver.reset()
        mock_transport.write.assert_called_once_with("*RST")
    def test_clear_status(self, mock_transport):
        """Test clear status command."""
        driver = BaseDriver(mock_transport)
        driver.clear_status()
        mock_transport.write.assert_called_once_with("*CLS")
    def test_operation_complete(self, mock_transport):
        """Test operation complete query."""
        mock_transport.query.return_value = "1"
        driver = BaseDriver(mock_transport)
        result = driver.operation_complete()
        assert result is True
        mock_transport.query.assert_called_once_with("*OPC?", None)
 class TestThermalChamberDriver:
    """Tests for ThermalChamberDriver."""
    def test_set_temperature(self, mock_transport):
        """Test temperature setpoint command."""
        driver = ThermalChamberDriver(mock_transport)
        driver.set_temperature(85.0)
        mock_transport.write.assert_called_once_with("TEMP:SETPOINT 85.00")
    def test_get_temperature(self, mock_transport):
        """Test temperature measurement query."""
        mock_transport.query.return_value = "25.50"
        driver = ThermalChamberDriver(mock_transport)
        temp = driver.get_temperature()
        assert temp == 25.5
        mock_transport.query.assert_called_once_with("TEMP:ACTUAL?", None)
    def test_get_setpoint(self, mock_transport):
        """Test setpoint query."""
        mock_transport.query.return_value = "85.00"
        driver = ThermalChamberDriver(mock_transport)
        setpoint = driver.get_setpoint()
        assert setpoint == 85.0
        mock_transport.query.assert_called_once_with("TEMP:SETPOINT?", None)
    def test_is_stable_true(self, mock_transport):
        """Test stability check - stable."""
        mock_transport.query.return_value = "1"
        driver = ThermalChamberDriver(mock_transport)
        assert driver.is_stable() is True
    def test_is_stable_false(self, mock_transport):
        """Test stability check - not stable."""
        mock_transport.query.return_value = "0"
        driver = ThermalChamberDriver(mock_transport)
        assert driver.is_stable() is False
    def test_wait_until_stable_immediate(self, mock_transport):
        """Test wait for stability - already stable."""
        mock_transport.query.return_value = "1"
        driver = ThermalChamberDriver(mock_transport)
        result = driver.wait_until_stable(timeout=5.0, poll_interval=0.1)
        assert result is True
    def test_wait_until_stable_timeout(self, mock_transport):
        """Test wait for stability - timeout."""
        mock_transport.query.return_value = "0"  # Never becomes stable
        driver = ThermalChamberDriver(mock_transport)
        result = driver.wait_until_stable(timeout=0.2, poll_interval=0.1)
        assert result is False
    def test_wait_until_stable_invalid_timeout(self, mock_transport):
        """Test wait with negative timeout."""
        driver = ThermalChamberDriver(mock_transport)
        with pytest.raises(ValueError, match="Timeout must be non-negative"):
            driver.wait_until_stable(timeout=-1.0)
    def test_wait_until_stable_invalid_interval(self, mock_transport):
        """Test wait with non-positive poll interval."""
        driver = ThermalChamberDriver(mock_transport)
        with pytest.raises(ValueError, match="Poll interval must be positive"):
            driver.wait_until_stable(poll_interval=0.0)
    def test_set_ramp_rate(self, mock_transport):
        """Test ramp rate command."""
        driver = ThermalChamberDriver(mock_transport)
        driver.set_ramp_rate(5.0)
        mock_transport.write.assert_called_once_with("TEMP:RAMP 5.00")
    def test_get_ramp_rate(self, mock_transport):
        """Test ramp rate query."""
        mock_transport.query.return_value = "5.00"
        driver = ThermalChamberDriver(mock_transport)
        rate = driver.get_ramp_rate()
        assert rate == 5.0
 class TestPowerSupplyDriver:
    """Tests for PowerSupplyDriver."""
    def test_set_voltage(self, mock_transport):
        """Test voltage setpoint command."""
        driver = PowerSupplyDriver(mock_transport)
        driver.set_voltage(1, 3.3)
        mock_transport.write.assert_called_once_with("VOLT 3.300")
    def test_get_voltage(self, mock_transport):
        """Test voltage setpoint query."""
        mock_transport.query.return_value = "3.300"
        driver = PowerSupplyDriver(mock_transport)
        voltage = driver.get_voltage(1)
        assert voltage == 3.3
    def test_set_current_limit(self, mock_transport):
        """Test current limit command."""
        driver = PowerSupplyDriver(mock_transport)
        driver.set_current_limit(1, 0.5)
        mock_transport.write.assert_called_once_with("CURR 0.500")
    def test_get_current_limit(self, mock_transport):
        """Test current limit query."""
        mock_transport.query.return_value = "0.500"
        driver = PowerSupplyDriver(mock_transport)
        current = driver.get_current_limit(1)
        assert current == 0.5
    def test_measure_voltage(self, mock_transport):
        """Test voltage measurement."""
        mock_transport.query.return_value = "3.305"
        driver = PowerSupplyDriver(mock_transport)
        voltage = driver.measure_voltage(1)
        assert voltage == 3.305
        mock_transport.query.assert_called_once_with("MEAS:VOLT?", None)
    def test_measure_current(self, mock_transport):
        """Test current measurement."""
        mock_transport.query.return_value = "0.125"
        driver = PowerSupplyDriver(mock_transport)
        current = driver.measure_current(1)
        assert current == 0.125
        mock_transport.query.assert_called_once_with("MEAS:CURR?", None)
    def test_enable_output_on(self, mock_transport):
        """Test enable output command."""
        driver = PowerSupplyDriver(mock_transport)
        driver.enable_output(1, True)
        mock_transport.write.assert_called_once_with("OUTP ON")
    def test_enable_output_off(self, mock_transport):
        """Test disable output command."""
        driver = PowerSupplyDriver(mock_transport)
        driver.enable_output(1, False)
        mock_transport.write.assert_called_once_with("OUTP OFF")
    def test_is_output_enabled_true(self, mock_transport):
        """Test output enabled query - enabled."""
        mock_transport.query.return_value = "1"
        driver = PowerSupplyDriver(mock_transport)
        assert driver.is_output_enabled(1) is True
    def test_is_output_enabled_false(self, mock_transport):
        """Test output enabled query - disabled."""
        mock_transport.query.return_value = "0"
        driver = PowerSupplyDriver(mock_transport)
        assert driver.is_output_enabled(1) is False
 class TestMultimeterDriver:
    """Tests for MultimeterDriver."""
    def test_measure_dc_voltage(self, mock_transport):
        """Test DC voltage measurement."""
        mock_transport.query.return_value = "3.300000"
        driver = MultimeterDriver(mock_transport)
        voltage = driver.measure_dc_voltage()
        assert voltage == 3.3
        mock_transport.query.assert_called_once_with("MEAS:VOLT:DC?", None)
    def test_measure_dc_current(self, mock_transport):
        """Test DC current measurement."""
        mock_transport.query.return_value = "0.125000"
        driver = MultimeterDriver(mock_transport)
        current = driver.measure_dc_current()
        assert current == 0.125
        mock_transport.query.assert_called_once_with("MEAS:CURR:DC?", None)
    def test_measure_resistance_not_implemented(self, mock_transport):
        """Test resistance measurement raises NotImplementedError."""
        driver = MultimeterDriver(mock_transport)
        with pytest.raises(NotImplementedError, match="Resistance measurement"):
            driver.measure_resistance()
    def test_set_integration_time_not_implemented(self, mock_transport):
        """Test integration time setting raises NotImplementedError."""
        driver = MultimeterDriver(mock_transport)
        with pytest.raises(NotImplementedError, match="Integration time"):
            driver.set_integration_time(1.0)
    def test_configure_dc_voltage(self, mock_transport):
        """Test configure for DC voltage."""
        driver = MultimeterDriver(mock_transport)
        driver.configure_dc_voltage()
        mock_transport.write.assert_called_once_with("CONF:VOLT:DC")
    def test_configure_dc_current(self, mock_transport):
        """Test configure for DC current."""
        driver = MultimeterDriver(mock_transport)
        driver.configure_dc_current()
        mock_transport.write.assert_called_once_with("CONF:CURR:DC")
    def test_get_configuration(self, mock_transport):
        """Test get current configuration."""
        mock_transport.query.return_value = '"VOLT:DC"'
        driver = MultimeterDriver(mock_transport)
        config = driver.get_configuration()
        assert config == "VOLT:DC"
        mock_transport.query.assert_called_once_with("CONF?", None)
    def test_read(self, mock_transport):
        """Test read measurement with current configuration."""
        mock_transport.query.return_value = "3.300000"
        driver = MultimeterDriver(mock_transport)
        value = driver.read()
        assert value == 3.3
        mock_transport.query.assert_called_once_with("READ?", None)
--- a/tests/unit/test_instruments.py
+++ b/tests/unit/test_instruments.py
@@ -0,0 +1,273 @@
 """Unit tests for instrument interfaces and factory.
 Tests the Hardware Abstraction Layer (HAL) interfaces and the factory
 pattern for creating instrument sets.
 """
 import pytest
 from py_dvt_ate.instruments import (
    IMultimeter,
    IPowerSupply,
    IThermalChamber,
    InstrumentConfig,
    InstrumentFactory,
    InstrumentSet,
 )
 from py_dvt_ate.instruments.drivers import (
    MultimeterDriver,
    PowerSupplyDriver,
    ThermalChamberDriver,
 )
 class TestInterfaceImplementation:
    """Test that drivers correctly implement the interface protocols."""
    def test_thermal_chamber_implements_interface(self):
        """Verify ThermalChamberDriver implements IThermalChamber."""
        # ABC inheritance ensures interface compliance at class definition time
        assert issubclass(ThermalChamberDriver, IThermalChamber)
    def test_power_supply_implements_interface(self):
        """Verify PowerSupplyDriver implements IPowerSupply."""
        assert issubclass(PowerSupplyDriver, IPowerSupply)
    def test_multimeter_implements_interface(self):
        """Verify MultimeterDriver implements IMultimeter."""
        assert issubclass(MultimeterDriver, IMultimeter)
    def test_thermal_chamber_has_all_methods(self):
        """Verify ThermalChamberDriver has all required methods."""
        required_methods = [
            "set_temperature",
            "get_temperature",
            "get_setpoint",
            "is_stable",
            "wait_until_stable",
            "set_ramp_rate",
        ]
        for method in required_methods:
            assert hasattr(ThermalChamberDriver, method)
    def test_power_supply_has_all_methods(self):
        """Verify PowerSupplyDriver has all required methods."""
        required_methods = [
            "set_voltage",
            "get_voltage",
            "set_current_limit",
            "get_current_limit",
            "measure_voltage",
            "measure_current",
            "enable_output",
            "is_output_enabled",
        ]
        for method in required_methods:
            assert hasattr(PowerSupplyDriver, method)
    def test_multimeter_has_all_methods(self):
        """Verify MultimeterDriver has all required methods."""
        required_methods = [
            "measure_dc_voltage",
            "measure_dc_current",
            "measure_resistance",
            "set_integration_time",
        ]
        for method in required_methods:
            assert hasattr(MultimeterDriver, method)
 class TestInstrumentSet:
    """Test the InstrumentSet dataclass."""
    def test_instrument_set_creation(self):
        """Verify InstrumentSet can be created with mock instruments."""
        from unittest.mock import Mock
        # Create mock instruments that satisfy the interface
        mock_chamber = Mock(spec=IThermalChamber)
        mock_psu = Mock(spec=IPowerSupply)
        mock_dmm = Mock(spec=IMultimeter)
        instrument_set = InstrumentSet(
            chamber=mock_chamber, psu=mock_psu, dmm=mock_dmm
        )
        assert instrument_set.chamber is mock_chamber
        assert instrument_set.psu is mock_psu
        assert instrument_set.dmm is mock_dmm
    def test_instrument_set_type_annotations(self):
        """Verify InstrumentSet has correct type annotations."""
        annotations = InstrumentSet.__annotations__
        assert annotations["chamber"] == IThermalChamber
        assert annotations["psu"] == IPowerSupply
        assert annotations["dmm"] == IMultimeter
 class TestInstrumentConfig:
    """Test the InstrumentConfig dataclass."""
    def test_config_defaults_simulator(self):
        """Verify default configuration for simulator backend."""
        config = InstrumentConfig(backend="simulator")
        assert config.backend == "simulator"
        assert config.simulator_host == "localhost"
        assert config.chamber_port == 5001
        assert config.psu_port == 5002
        assert config.dmm_port == 5003
        assert config.chamber_visa is None
        assert config.psu_visa is None
        assert config.dmm_visa is None
    def test_config_custom_ports(self):
        """Verify configuration accepts custom port settings."""
        config = InstrumentConfig(
            backend="simulator",
            simulator_host="192.168.1.100",
            chamber_port=6001,
            psu_port=6002,
            dmm_port=6003,
        )
        assert config.simulator_host == "192.168.1.100"
        assert config.chamber_port == 6001
        assert config.psu_port == 6002
        assert config.dmm_port == 6003
    def test_config_pyvisa_backend(self):
        """Verify configuration for PyVISA backend."""
        config = InstrumentConfig(
            backend="pyvisa",
            chamber_visa="TCPIP::192.168.1.10::INSTR",
            psu_visa="TCPIP::192.168.1.11::INSTR",
            dmm_visa="TCPIP::192.168.1.12::INSTR",
        )
        assert config.backend == "pyvisa"
        assert config.chamber_visa == "TCPIP::192.168.1.10::INSTR"
        assert config.psu_visa == "TCPIP::192.168.1.11::INSTR"
        assert config.dmm_visa == "TCPIP::192.168.1.12::INSTR"
 class TestInstrumentFactory:
    """Test the InstrumentFactory."""
    def test_factory_rejects_unknown_backend(self):
        """Verify factory raises error for unknown backend."""
        config = InstrumentConfig(backend="invalid")  # type: ignore
        with pytest.raises(ValueError, match="Unknown backend: invalid"):
            InstrumentFactory.create(config)
    def test_factory_pyvisa_not_implemented(self):
        """Verify PyVISA backend raises NotImplementedError."""
        config = InstrumentConfig(backend="pyvisa")
        with pytest.raises(NotImplementedError, match="PyVISA backend not yet"):
            InstrumentFactory.create(config)
    def test_factory_creates_instrument_set(self):
        """Verify factory creates InstrumentSet with correct structure."""
        from unittest.mock import Mock, patch
        config = InstrumentConfig(backend="simulator")
        # Mock the transports and drivers to avoid actual connections
        # Patch where they're imported FROM, not where they're used
        with (
            patch(
                "py_dvt_ate.instruments.transport.tcp.TCPTransport"
            ) as mock_tcp_transport,
            patch(
                "py_dvt_ate.instruments.drivers.chamber.ThermalChamberDriver"
            ) as mock_chamber,
            patch(
                "py_dvt_ate.instruments.drivers.power_supply.PowerSupplyDriver"
            ) as mock_psu,
            patch(
                "py_dvt_ate.instruments.drivers.multimeter.MultimeterDriver"
            ) as mock_dmm,
        ):
            # Create mock instrument instances
            mock_chamber_instance = Mock(spec=IThermalChamber)
            mock_psu_instance = Mock(spec=IPowerSupply)
            mock_dmm_instance = Mock(spec=IMultimeter)
            mock_chamber.return_value = mock_chamber_instance
            mock_psu.return_value = mock_psu_instance
            mock_dmm.return_value = mock_dmm_instance
            instrument_set = InstrumentFactory.create(config)
            # Verify InstrumentSet was created
            assert isinstance(instrument_set, InstrumentSet)
            # Verify transports were created with correct parameters
            assert mock_tcp_transport.call_count == 3
            mock_tcp_transport.assert_any_call("localhost", 5001)  # chamber
            mock_tcp_transport.assert_any_call("localhost", 5002)  # psu
            mock_tcp_transport.assert_any_call("localhost", 5003)  # dmm
            # Verify drivers were created
            assert mock_chamber.call_count == 1
            assert mock_psu.call_count == 1
            assert mock_dmm.call_count == 1
            # Verify InstrumentSet contains the mock instances
            assert instrument_set.chamber is mock_chamber_instance
            assert instrument_set.psu is mock_psu_instance
            assert instrument_set.dmm is mock_dmm_instance
    def test_factory_uses_custom_ports(self):
        """Verify factory uses custom port configuration."""
        from unittest.mock import patch
        config = InstrumentConfig(
            backend="simulator",
            simulator_host="testserver",
            chamber_port=7001,
            psu_port=7002,
            dmm_port=7003,
        )
        with patch(
            "py_dvt_ate.instruments.transport.tcp.TCPTransport"
        ) as mock_tcp_transport:
            InstrumentFactory.create(config)
            # Verify custom host and ports were used
            mock_tcp_transport.assert_any_call("testserver", 7001)
            mock_tcp_transport.assert_any_call("testserver", 7002)
            mock_tcp_transport.assert_any_call("testserver", 7003)
    def test_factory_returns_correct_types(self):
        """Verify factory returns instruments implementing correct interfaces."""
        from unittest.mock import Mock, patch
        config = InstrumentConfig(backend="simulator")
        with (
            patch("py_dvt_ate.instruments.transport.tcp.TCPTransport"),
            patch(
                "py_dvt_ate.instruments.drivers.chamber.ThermalChamberDriver"
            ) as mock_chamber,
            patch(
                "py_dvt_ate.instruments.drivers.power_supply.PowerSupplyDriver"
            ) as mock_psu,
            patch(
                "py_dvt_ate.instruments.drivers.multimeter.MultimeterDriver"
            ) as mock_dmm,
        ):
            # Make the mocks subclasses of the interfaces
            mock_chamber.return_value = Mock(spec=IThermalChamber)
            mock_psu.return_value = Mock(spec=IPowerSupply)
            mock_dmm.return_value = Mock(spec=IMultimeter)
            instrument_set = InstrumentFactory.create(config)
            # Verify returned instruments satisfy the interface specs
            # (Mock with spec=Interface makes isinstance checks work)
            assert isinstance(instrument_set, InstrumentSet)
--- a/tests/unit/test_multimeter.py
+++ b/tests/unit/test_multimeter.py
@@ -0,0 +1,306 @@
 """Unit tests for multimeter simulator."""
 import pytest
 from py_dvt_ate.simulation.physics.engine import PhysicsEngine
 from py_dvt_ate.simulation.virtual.multimeter import MultimeterSim
 class TestMultimeterSimBasic:
    """Tests for MultimeterSim without physics engine."""
    @pytest.fixture
    def dmm(self) -> MultimeterSim:
        """Create multimeter instance without physics engine."""
        return MultimeterSim()
    def test_creation(self, dmm: MultimeterSim) -> None:
        """Test multimeter can be created."""
        assert dmm is not None
        assert dmm.model == "DMM-SIM-001"
        assert dmm.manufacturer == "PyDVTATE"
    def test_idn_query(self, dmm: MultimeterSim) -> None:
        """Test *IDN? returns identification string."""
        response = dmm.process("*IDN?")
        assert "PyDVTATE" in response
        assert "DMM-SIM-001" in response
    def test_rst_command(self, dmm: MultimeterSim) -> None:
        """Test *RST resets to defaults."""
        # Set non-default config
        dmm.process("CONF:CURR:DC")
        assert dmm.process("CONF?") == '"CURR:DC"'
        # Reset
        response = dmm.process("*RST")
        assert response == ""
        # Check defaults restored
        assert dmm.process("CONF?") == '"VOLT:DC"'
    def test_opc_query(self, dmm: MultimeterSim) -> None:
        """Test *OPC? returns 1."""
        response = dmm.process("*OPC?")
        assert response == "1"
    def test_unknown_command(self, dmm: MultimeterSim) -> None:
        """Test unknown command returns error."""
        response = dmm.process("INVALID:CMD")
        assert response.startswith("ERROR:")
        assert "Unknown command" in response
 class TestMultimeterMeasVoltDC:
    """Tests for MEAS:VOLT:DC command."""
    @pytest.fixture
    def dmm(self) -> MultimeterSim:
        """Create multimeter instance without physics engine."""
        return MultimeterSim()
    def test_meas_volt_dc_query_no_engine(self, dmm: MultimeterSim) -> None:
        """Test MEAS:VOLT:DC? returns 0 without physics engine."""
        response = dmm.process("MEAS:VOLT:DC?")
        assert response == "0.000000"
    def test_meas_volt_dc_sets_config(self, dmm: MultimeterSim) -> None:
        """Test MEAS:VOLT:DC? sets configuration to VOLT:DC."""
        dmm.process("CONF:CURR:DC")
        dmm.process("MEAS:VOLT:DC?")
        assert dmm.process("CONF?") == '"VOLT:DC"'
    def test_meas_volt_dc_as_command_fails(self, dmm: MultimeterSim) -> None:
        """Test MEAS:VOLT:DC (without ?) returns error."""
        response = dmm.process("MEAS:VOLT:DC 1.0")
        assert response.startswith("ERROR:")
        assert "query only" in response
 class TestMultimeterMeasCurrDC:
    """Tests for MEAS:CURR:DC command."""
    @pytest.fixture
    def dmm(self) -> MultimeterSim:
        """Create multimeter instance without physics engine."""
        return MultimeterSim()
    def test_meas_curr_dc_query_no_engine(self, dmm: MultimeterSim) -> None:
        """Test MEAS:CURR:DC? returns 0 without physics engine."""
        response = dmm.process("MEAS:CURR:DC?")
        assert response == "0.000000"
    def test_meas_curr_dc_sets_config(self, dmm: MultimeterSim) -> None:
        """Test MEAS:CURR:DC? sets configuration to CURR:DC."""
        dmm.process("MEAS:CURR:DC?")
        assert dmm.process("CONF?") == '"CURR:DC"'
    def test_meas_curr_dc_as_command_fails(self, dmm: MultimeterSim) -> None:
        """Test MEAS:CURR:DC (without ?) returns error."""
        response = dmm.process("MEAS:CURR:DC 0.1")
        assert response.startswith("ERROR:")
        assert "query only" in response
 class TestMultimeterConf:
    """Tests for CONF commands."""
    @pytest.fixture
    def dmm(self) -> MultimeterSim:
        """Create multimeter instance without physics engine."""
        return MultimeterSim()
    def test_conf_query_default(self, dmm: MultimeterSim) -> None:
        """Test CONF? returns default configuration."""
        response = dmm.process("CONF?")
        assert response == '"VOLT:DC"'
    def test_conf_volt_dc(self, dmm: MultimeterSim) -> None:
        """Test CONF:VOLT:DC sets voltage measurement mode."""
        dmm.process("CONF:CURR:DC")
        response = dmm.process("CONF:VOLT:DC")
        assert response == ""
        assert dmm.process("CONF?") == '"VOLT:DC"'
    def test_conf_volt_dc_as_query_fails(self, dmm: MultimeterSim) -> None:
        """Test CONF:VOLT:DC? returns error."""
        response = dmm.process("CONF:VOLT:DC?")
        assert response.startswith("ERROR:")
        assert "command only" in response
    def test_conf_curr_dc(self, dmm: MultimeterSim) -> None:
        """Test CONF:CURR:DC sets current measurement mode."""
        response = dmm.process("CONF:CURR:DC")
        assert response == ""
        assert dmm.process("CONF?") == '"CURR:DC"'
    def test_conf_curr_dc_as_query_fails(self, dmm: MultimeterSim) -> None:
        """Test CONF:CURR:DC? returns error."""
        response = dmm.process("CONF:CURR:DC?")
        assert response.startswith("ERROR:")
        assert "command only" in response
    def test_conf_as_command_fails(self, dmm: MultimeterSim) -> None:
        """Test CONF without subcommand returns error."""
        response = dmm.process("CONF")
        assert response.startswith("ERROR:")
 class TestMultimeterRead:
    """Tests for READ command."""
    @pytest.fixture
    def dmm(self) -> MultimeterSim:
        """Create multimeter instance without physics engine."""
        return MultimeterSim()
    def test_read_query_volt_mode(self, dmm: MultimeterSim) -> None:
        """Test READ? returns voltage when configured for voltage."""
        dmm.process("CONF:VOLT:DC")
        response = dmm.process("READ?")
        assert response == "0.000000"
    def test_read_query_curr_mode(self, dmm: MultimeterSim) -> None:
        """Test READ? returns current when configured for current."""
        dmm.process("CONF:CURR:DC")
        response = dmm.process("READ?")
        assert response == "0.000000"
    def test_read_as_command_fails(self, dmm: MultimeterSim) -> None:
        """Test READ (without ?) returns error."""
        response = dmm.process("READ")
        assert response.startswith("ERROR:")
        assert "query only" in response
 class TestMultimeterWithPhysicsEngine:
    """Tests for MultimeterSim with physics engine integration."""
    @pytest.fixture
    def engine(self) -> PhysicsEngine:
        """Create physics engine instance."""
        return PhysicsEngine(update_rate_hz=100.0)
    @pytest.fixture
    def dmm(self, engine: PhysicsEngine) -> MultimeterSim:
        """Create multimeter instance with physics engine."""
        return MultimeterSim(physics_engine=engine)
    def test_meas_volt_dc_returns_engine_voltage(
        self, dmm: MultimeterSim, engine: PhysicsEngine
    ) -> None:
        """Test MEAS:VOLT:DC? returns physics engine output voltage."""
        engine.set_input_voltage(5.0)
        engine.set_output_enabled(True)
        engine.step()
        response = dmm.process("MEAS:VOLT:DC?")
        # LDO model outputs ~3.3V nominal
        voltage = float(response)
        assert voltage > 3.0
        assert voltage < 4.0
    def test_meas_volt_dc_returns_zero_when_disabled(
        self, dmm: MultimeterSim, engine: PhysicsEngine
    ) -> None:
        """Test MEAS:VOLT:DC? returns 0 when DUT output disabled."""
        engine.set_input_voltage(5.0)
        engine.set_output_enabled(False)
        engine.step()
        response = dmm.process("MEAS:VOLT:DC?")
        assert response == "0.000000"
    def test_meas_curr_dc_returns_engine_current(
        self, dmm: MultimeterSim, engine: PhysicsEngine
    ) -> None:
        """Test MEAS:CURR:DC? returns physics engine load current."""
        engine.set_input_voltage(5.0)
        engine.set_load_current(0.1)
        engine.set_output_enabled(True)
        engine.step()
        response = dmm.process("MEAS:CURR:DC?")
        assert float(response) == pytest.approx(0.1, abs=0.001)
    def test_meas_curr_dc_returns_zero_when_disabled(
        self, dmm: MultimeterSim, engine: PhysicsEngine
    ) -> None:
        """Test MEAS:CURR:DC? returns 0 when DUT output disabled."""
        engine.set_input_voltage(5.0)
        engine.set_load_current(0.1)
        engine.set_output_enabled(False)
        engine.step()
        response = dmm.process("MEAS:CURR:DC?")
        assert response == "0.000000"
    def test_read_uses_configured_function(
        self, dmm: MultimeterSim, engine: PhysicsEngine
    ) -> None:
        """Test READ? respects configured measurement function."""
        engine.set_input_voltage(5.0)
        engine.set_load_current(0.1)
        engine.set_output_enabled(True)
        engine.step()
        # Configure for current
        dmm.process("CONF:CURR:DC")
        response = dmm.process("READ?")
        # Should return current, not voltage
        assert float(response) == pytest.approx(0.1, abs=0.001)
    def test_reset_restores_voltage_mode(
        self, dmm: MultimeterSim, engine: PhysicsEngine
    ) -> None:
        """Test *RST restores default voltage measurement mode."""
        dmm.process("CONF:CURR:DC")
        dmm.process("*RST")
        assert dmm.process("CONF?") == '"VOLT:DC"'
    def test_voltage_changes_with_temperature(
        self, dmm: MultimeterSim, engine: PhysicsEngine
    ) -> None:
        """Test measured voltage changes with DUT temperature."""
        engine.set_input_voltage(5.0)
        engine.set_output_enabled(True)
        engine.step()
        # Measure at initial temperature
        response1 = dmm.process("MEAS:VOLT:DC?")
        v1 = float(response1)
        # Change chamber temperature and let settle
        engine.set_chamber_setpoint(85.0)
        for _ in range(5000):  # Let temperature settle somewhat
            engine.step()
        # Measure at elevated temperature
        response2 = dmm.process("MEAS:VOLT:DC?")
        v2 = float(response2)
        # Output voltage should have changed (LDO has tempco)
        assert v1 != v2
--- a/tests/unit/test_physics_engine.py
+++ b/tests/unit/test_physics_engine.py
@@ -0,0 +1,300 @@
 """Integration tests for the physics engine with thermal-electrical coupling.
 Tests the complete physics simulation including:
 - Thermal settling behaviour (chamber, case, junction)
 - Self-heating effects from power dissipation
 - Temperature-dependent electrical behaviour
 """
 import pytest
 from py_dvt_ate.simulation.physics.engine import PhysicsEngine
 from py_dvt_ate.simulation.physics.models.ldo import LDOModel, LDOParameters
 class TestThermalSettling:
    """Tests for thermal settling behaviour."""
    def test_chamber_approaches_setpoint(self) -> None:
        """Test chamber temperature approaches setpoint over time."""
        engine = PhysicsEngine(update_rate_hz=100.0)
        # Set a new setpoint
        engine.set_chamber_setpoint(85.0)
        # Initial state
        initial_state = engine.get_thermal_state()
        assert initial_state.chamber_temperature == pytest.approx(25.0)
        # Simulate for 1 second (100 steps at 100Hz)
        for _ in range(100):
            engine.step()
        state_1s = engine.get_thermal_state()
        # Chamber should have moved towards 85°C but not reached it yet
        # With tau=30s, after 1s: T = 25 + (85-25)*(1 - e^(-1/30)) ≈ 27.0°C
        assert state_1s.chamber_temperature > 25.0
        assert state_1s.chamber_temperature < 85.0
        # Simulate for another 89 seconds (total 90s = 3*tau)
        for _ in range(8900):
            engine.step()
        state_90s = engine.get_thermal_state()
        # After 3 time constants, should be ~95% of the way there
        # T = 25 + (85-25)*(1 - e^(-3)) ≈ 82.0°C
        assert state_90s.chamber_temperature > 80.0
        assert state_90s.chamber_temperature < 85.0
    def test_case_follows_chamber(self) -> None:
        """Test case temperature follows chamber temperature."""
        engine = PhysicsEngine(update_rate_hz=100.0)
        # Set chamber to high temperature (no power, so no self-heating)
        engine.set_chamber_setpoint(85.0)
        # Simulate for 200 seconds (well past both time constants)
        for _ in range(20000):
            engine.step()
        state = engine.get_thermal_state()
        # With no power, case should approach chamber temperature
        assert state.case_temperature == pytest.approx(
            state.chamber_temperature, abs=0.5
        )
    def test_junction_equals_case_with_no_power(self) -> None:
        """Test junction equals case temperature when no power dissipated."""
        engine = PhysicsEngine(update_rate_hz=100.0)
        # No power applied (output disabled by default)
        state = engine.get_thermal_state()
        # Junction should equal case (no θ_jc rise with zero power)
        assert state.junction_temperature == pytest.approx(state.case_temperature)
 class TestSelfHeating:
    """Tests for self-heating effects from power dissipation."""
    def test_junction_higher_than_case_with_power(self) -> None:
        """Test junction temperature rises above case when power is dissipated."""
        engine = PhysicsEngine(update_rate_hz=100.0)
        # Apply power: 5V input, 100mA load
        engine.set_input_voltage(5.0)
        engine.set_load_current(0.1)
        engine.set_output_enabled(True)
        # Let it settle
        for _ in range(1000):
            engine.step()
        thermal_state = engine.get_thermal_state()
        electrical_state = engine.get_electrical_state()
        # Power dissipation = (Vin - Vout) * Iload + Vin * Iq
        # With Vout ≈ 3.3V, P ≈ (5-3.3)*0.1 ≈ 0.17W
        assert electrical_state.power_dissipation > 0
        # Junction should be higher than case by P * θ_jc
        # θ_jc = 15°C/W, so with 0.17W, ΔT ≈ 2.5°C
        assert (
            thermal_state.junction_temperature > thermal_state.case_temperature
        )
    def test_self_heating_raises_case_temperature(self) -> None:
        """Test self-heating raises case temperature above ambient."""
        engine = PhysicsEngine(update_rate_hz=100.0)
        # Apply significant power: 5V input, 300mA load
        engine.set_input_voltage(5.0)
        engine.set_load_current(0.3)
        engine.set_output_enabled(True)
        # Let thermal state settle (many time constants)
        for _ in range(50000):  # 500 seconds at 100Hz
            engine.step()
        thermal_state = engine.get_thermal_state()
        # Power ≈ (5-3.3)*0.3 ≈ 0.51W
        # Steady-state case rise = P * θ_ca = 0.51 * 5 ≈ 2.5°C
        # Case should be above chamber temperature
        assert (
            thermal_state.case_temperature > thermal_state.chamber_temperature
        )
    def test_self_heating_increases_with_load(self) -> None:
        """Test that self-heating increases with higher load current."""
        engine1 = PhysicsEngine(update_rate_hz=100.0)
        engine2 = PhysicsEngine(update_rate_hz=100.0)
        # Both at 5V, but different loads
        for engine, load in [(engine1, 0.1), (engine2, 0.3)]:
            engine.set_input_voltage(5.0)
            engine.set_load_current(load)
            engine.set_output_enabled(True)
            # Let settle
            for _ in range(50000):
                engine.step()
        state1 = engine1.get_thermal_state()
        state2 = engine2.get_thermal_state()
        # Higher load should give higher junction temperature
        assert (
            state2.junction_temperature > state1.junction_temperature
        )
 class TestTemperatureDependentElectrical:
    """Tests for temperature-dependent electrical behaviour."""
    def test_output_voltage_varies_with_temperature(self) -> None:
        """Test output voltage changes with junction temperature."""
        # Create custom LDO with higher tempco for observable effect
        params = LDOParameters(
            nominal_output_voltage=3.3,
            tempco_ppm_per_c=100.0,  # 100 ppm/°C for visible effect
        )
        ldo = LDOModel(params=params)
        # Test at different temperatures
        vout_25 = ldo.calculate_output_voltage(25.0)
        vout_85 = ldo.calculate_output_voltage(85.0)
        # At 85°C with 100 ppm/°C:
        # ΔV = 3.3 * 100e-6 * 60 = 19.8mV
        delta_v = vout_85 - vout_25
        expected_delta = 3.3 * 100e-6 * 60
        assert delta_v == pytest.approx(expected_delta, rel=0.01)
    def test_quiescent_current_varies_with_temperature(self) -> None:
        """Test quiescent current changes with junction temperature."""
        ldo = LDOModel()
        # Test at different temperatures
        iq_25 = ldo.calculate_quiescent_current(25.0)
        iq_85 = ldo.calculate_quiescent_current(85.0)
        # Default tempco is 0.003/°C (0.3%/°C)
        # At 85°C: Iq = Iq_25 * (1 + 0.003 * 60) = Iq_25 * 1.18
        expected_ratio = 1.0 + 0.003 * 60
        assert iq_85 / iq_25 == pytest.approx(expected_ratio, rel=0.01)
    def test_power_dissipation_calculation(self) -> None:
        """Test power dissipation is calculated correctly."""
        ldo = LDOModel()
        ldo.input_voltage = 5.0
        # P = (Vin - Vout) * Iload + Vin * Iq
        # At 25°C: Vout ≈ 3.3V, Iq ≈ 50µA
        # With 100mA load: P ≈ (5-3.3)*0.1 + 5*50e-6 ≈ 0.170W
        p_diss = ldo.calculate_power_dissipation(
            input_voltage=5.0,
            load_current=0.1,
            junction_temperature=25.0,
        )
        expected_p = (5.0 - 3.3) * 0.1 + 5.0 * 50e-6
        assert p_diss == pytest.approx(expected_p, rel=0.01)
 class TestPhysicsEngineCoupling:
    """Tests for complete thermal-electrical coupling in the engine."""
    def test_thermal_electrical_feedback(self) -> None:
        """Test that thermal and electrical states are coupled.
        Higher junction temperature affects Vout, which affects power
        dissipation, which affects junction temperature - a feedback loop.
        """
        engine = PhysicsEngine(update_rate_hz=100.0)
        # Apply power at hot chamber
        engine.set_chamber_setpoint(85.0)
        engine.set_input_voltage(5.0)
        engine.set_load_current(0.2)
        engine.set_output_enabled(True)
        # Let settle completely
        for _ in range(100000):  # 1000 seconds
            engine.step()
        thermal = engine.get_thermal_state()
        electrical = engine.get_electrical_state()
        # Verify the coupling:
        # 1. Chamber should be near 85°C
        assert thermal.chamber_temperature == pytest.approx(85.0, abs=0.5)
        # 2. Case should be higher than chamber due to self-heating
        assert thermal.case_temperature > thermal.chamber_temperature
        # 3. Junction should be higher than case
        assert thermal.junction_temperature > thermal.case_temperature
        # 4. Output voltage should reflect temperature-adjusted value
        assert electrical.output_voltage > 0
        assert electrical.output_voltage < 5.0  # Less than input
        # 5. Power should be non-zero
        assert electrical.power_dissipation > 0
    def test_engine_with_custom_dut_model(self) -> None:
        """Test engine works with custom DUT model parameters."""
        params = LDOParameters(
            nominal_output_voltage=1.8,  # Different voltage
            tempco_ppm_per_c=25.0,
        )
        ldo = LDOModel(params=params)
        engine = PhysicsEngine(update_rate_hz=100.0, dut_model=ldo)
        engine.set_input_voltage(3.3)
        engine.set_load_current(0.1)
        engine.set_output_enabled(True)
        for _ in range(1000):
            engine.step()
        electrical = engine.get_electrical_state()
        # Should output approximately 1.8V
        assert electrical.output_voltage == pytest.approx(1.8, abs=0.01)
    def test_simulation_time_accuracy(self) -> None:
        """Test simulation time accumulates correctly."""
        engine = PhysicsEngine(update_rate_hz=1000.0)  # 1ms timestep
        for _ in range(1000):
            engine.step()
        # Should be exactly 1 second
        assert engine.simulation_time == pytest.approx(1.0, abs=1e-6)
    def test_multiple_setpoint_changes(self) -> None:
        """Test engine handles multiple setpoint changes correctly."""
        engine = PhysicsEngine(update_rate_hz=100.0)
        # Start at 25°C, go to 85°C
        engine.set_chamber_setpoint(85.0)
        for _ in range(10000):  # 100 seconds
            engine.step()
        hot_state = engine.get_thermal_state()
        assert hot_state.chamber_temperature > 75.0
        # Now cool down to -40°C
        engine.set_chamber_setpoint(-40.0)
        for _ in range(20000):  # 200 seconds
            engine.step()
        cold_state = engine.get_thermal_state()
        assert cold_state.chamber_temperature < -30.0
--- a/tests/unit/test_physics_models.py
+++ b/tests/unit/test_physics_models.py
@@ -0,0 +1,214 @@
 """Unit tests for physics state dataclasses and engine stub."""
 import pytest
 from py_dvt_ate.simulation.physics.engine import PhysicsEngine
 from py_dvt_ate.simulation.physics.state import ElectricalState, ThermalState
 class TestThermalState:
    """Tests for the ThermalState dataclass."""
    def test_creation(self) -> None:
        """Test ThermalState can be created with valid values."""
        state = ThermalState(
            chamber_temperature=25.0,
            case_temperature=30.0,
            junction_temperature=35.0,
            timestamp=0.0,
        )
        assert state.chamber_temperature == 25.0
        assert state.case_temperature == 30.0
        assert state.junction_temperature == 35.0
        assert state.timestamp == 0.0
    def test_immutability(self) -> None:
        """Test ThermalState is immutable (frozen dataclass)."""
        state = ThermalState(
            chamber_temperature=25.0,
            case_temperature=30.0,
            junction_temperature=35.0,
            timestamp=0.0,
        )
        with pytest.raises(AttributeError):
            state.chamber_temperature = 50.0  # type: ignore[misc]
    def test_equality(self) -> None:
        """Test ThermalState equality comparison."""
        state1 = ThermalState(
            chamber_temperature=25.0,
            case_temperature=30.0,
            junction_temperature=35.0,
            timestamp=0.0,
        )
        state2 = ThermalState(
            chamber_temperature=25.0,
            case_temperature=30.0,
            junction_temperature=35.0,
            timestamp=0.0,
        )
        assert state1 == state2
    def test_hashable(self) -> None:
        """Test ThermalState is hashable (for use in sets/dicts)."""
        state = ThermalState(
            chamber_temperature=25.0,
            case_temperature=30.0,
            junction_temperature=35.0,
            timestamp=0.0,
        )
        # Should not raise
        hash(state)
        _ = {state}  # Can be added to a set
 class TestElectricalState:
    """Tests for the ElectricalState dataclass."""
    def test_creation(self) -> None:
        """Test ElectricalState can be created with valid values."""
        state = ElectricalState(
            input_voltage=5.0,
            output_voltage=3.3,
            load_current=0.1,
            quiescent_current=50e-6,
            power_dissipation=0.17,
        )
        assert state.input_voltage == 5.0
        assert state.output_voltage == 3.3
        assert state.load_current == 0.1
        assert state.quiescent_current == 50e-6
        assert state.power_dissipation == 0.17
    def test_immutability(self) -> None:
        """Test ElectricalState is immutable (frozen dataclass)."""
        state = ElectricalState(
            input_voltage=5.0,
            output_voltage=3.3,
            load_current=0.1,
            quiescent_current=50e-6,
            power_dissipation=0.17,
        )
        with pytest.raises(AttributeError):
            state.output_voltage = 1.8  # type: ignore[misc]
    def test_equality(self) -> None:
        """Test ElectricalState equality comparison."""
        state1 = ElectricalState(
            input_voltage=5.0,
            output_voltage=3.3,
            load_current=0.1,
            quiescent_current=50e-6,
            power_dissipation=0.17,
        )
        state2 = ElectricalState(
            input_voltage=5.0,
            output_voltage=3.3,
            load_current=0.1,
            quiescent_current=50e-6,
            power_dissipation=0.17,
        )
        assert state1 == state2
 class TestPhysicsEngineStub:
    """Tests for the PhysicsEngine stub."""
    def test_creation_default(self) -> None:
        """Test PhysicsEngine can be created with defaults."""
        engine = PhysicsEngine()
        assert engine.dt == pytest.approx(0.01)  # 100Hz -> 10ms
    def test_creation_custom_rate(self) -> None:
        """Test PhysicsEngine with custom update rate."""
        engine = PhysicsEngine(update_rate_hz=50.0)
        assert engine.dt == pytest.approx(0.02)  # 50Hz -> 20ms
    def test_step_advances_time(self) -> None:
        """Test step() advances simulation time."""
        engine = PhysicsEngine(update_rate_hz=100.0)
        assert engine.simulation_time == pytest.approx(0.0)
        engine.step()
        assert engine.simulation_time == pytest.approx(0.01)
        engine.step()
        assert engine.simulation_time == pytest.approx(0.02)
    def test_get_thermal_state(self) -> None:
        """Test get_thermal_state returns ThermalState."""
        engine = PhysicsEngine()
        state = engine.get_thermal_state()
        assert isinstance(state, ThermalState)
        assert state.chamber_temperature == 25.0  # Default
        assert state.timestamp == 0.0
    def test_get_electrical_state(self) -> None:
        """Test get_electrical_state returns ElectricalState."""
        engine = PhysicsEngine()
        state = engine.get_electrical_state()
        assert isinstance(state, ElectricalState)
    def test_set_chamber_setpoint(self) -> None:
        """Test set_chamber_setpoint updates setpoint."""
        engine = PhysicsEngine()
        engine.set_chamber_setpoint(85.0)
        # Stub doesn't update chamber temp, just stores setpoint
        state = engine.get_thermal_state()
        assert state.chamber_temperature == 25.0  # Still at initial
    def test_set_input_voltage(self) -> None:
        """Test set_input_voltage updates voltage."""
        engine = PhysicsEngine()
        engine.set_input_voltage(5.0)
        state = engine.get_electrical_state()
        assert state.input_voltage == 5.0
    def test_set_load_current(self) -> None:
        """Test set_load_current updates current."""
        engine = PhysicsEngine()
        engine.set_output_enabled(True)
        engine.set_load_current(0.1)
        state = engine.get_electrical_state()
        assert state.load_current == 0.1
    def test_output_disabled_by_default(self) -> None:
        """Test output is disabled by default."""
        engine = PhysicsEngine()
        assert not engine.is_output_enabled
    def test_enable_output(self) -> None:
        """Test set_output_enabled enables output."""
        engine = PhysicsEngine()
        engine.set_output_enabled(True)
        assert engine.is_output_enabled
    def test_load_current_zero_when_disabled(self) -> None:
        """Test load current is zero when output disabled."""
        engine = PhysicsEngine()
        engine.set_load_current(0.1)
        state = engine.get_electrical_state()
        assert state.load_current == 0.0  # Disabled, so zero
--- a/tests/unit/test_power_supply.py
+++ b/tests/unit/test_power_supply.py
@@ -0,0 +1,352 @@
 """Unit tests for power supply simulator."""
 import pytest
 from py_dvt_ate.simulation.physics.engine import PhysicsEngine
 from py_dvt_ate.simulation.virtual.power_supply import PowerSupplySim
 class TestPowerSupplySimBasic:
    """Tests for PowerSupplySim without physics engine."""
    @pytest.fixture
    def psu(self) -> PowerSupplySim:
        """Create power supply instance without physics engine."""
        return PowerSupplySim()
    def test_creation(self, psu: PowerSupplySim) -> None:
        """Test power supply can be created."""
        assert psu is not None
        assert psu.model == "PS-SIM-001"
        assert psu.manufacturer == "PyDVTATE"
    def test_idn_query(self, psu: PowerSupplySim) -> None:
        """Test *IDN? returns identification string."""
        response = psu.process("*IDN?")
        assert "PyDVTATE" in response
        assert "PS-SIM-001" in response
    def test_rst_command(self, psu: PowerSupplySim) -> None:
        """Test *RST resets to defaults."""
        # Set non-default values
        psu.process("VOLT 12.0")
        psu.process("CURR 2.0")
        psu.process("OUTP ON")
        # Reset
        response = psu.process("*RST")
        assert response == ""
        # Check defaults restored
        assert psu.process("VOLT?") == "0.000"
        assert psu.process("CURR?") == "1.000"
        assert psu.process("OUTP?") == "0"
    def test_opc_query(self, psu: PowerSupplySim) -> None:
        """Test *OPC? returns 1."""
        response = psu.process("*OPC?")
        assert response == "1"
    def test_unknown_command(self, psu: PowerSupplySim) -> None:
        """Test unknown command returns error."""
        response = psu.process("INVALID:CMD")
        assert response.startswith("ERROR:")
        assert "Unknown command" in response
 class TestPowerSupplyVoltage:
    """Tests for VOLT command."""
    @pytest.fixture
    def psu(self) -> PowerSupplySim:
        """Create power supply instance without physics engine."""
        return PowerSupplySim()
    def test_volt_query_default(self, psu: PowerSupplySim) -> None:
        """Test VOLT? returns default value."""
        response = psu.process("VOLT?")
        assert response == "0.000"
    def test_volt_set(self, psu: PowerSupplySim) -> None:
        """Test VOLT sets value."""
        response = psu.process("VOLT 12.5")
        assert response == ""
        assert psu.process("VOLT?") == "12.500"
    def test_volt_set_decimal(self, psu: PowerSupplySim) -> None:
        """Test VOLT accepts decimal values."""
        psu.process("VOLT 3.3")
        assert psu.process("VOLT?") == "3.300"
    def test_volt_set_negative_fails(self, psu: PowerSupplySim) -> None:
        """Test VOLT rejects negative values."""
        response = psu.process("VOLT -5.0")
        assert response.startswith("ERROR:")
        assert "negative" in response
    def test_volt_set_invalid_value(self, psu: PowerSupplySim) -> None:
        """Test VOLT with invalid value returns error."""
        response = psu.process("VOLT abc")
        assert response.startswith("ERROR:")
        assert "Invalid voltage" in response
    def test_volt_set_no_argument(self, psu: PowerSupplySim) -> None:
        """Test VOLT without argument returns error."""
        response = psu.process("VOLT")
        assert response.startswith("ERROR:")
        assert "requires a value" in response
 class TestPowerSupplyCurrent:
    """Tests for CURR command."""
    @pytest.fixture
    def psu(self) -> PowerSupplySim:
        """Create power supply instance without physics engine."""
        return PowerSupplySim()
    def test_curr_query_default(self, psu: PowerSupplySim) -> None:
        """Test CURR? returns default value."""
        response = psu.process("CURR?")
        assert response == "1.000"
    def test_curr_set(self, psu: PowerSupplySim) -> None:
        """Test CURR sets value."""
        response = psu.process("CURR 0.5")
        assert response == ""
        assert psu.process("CURR?") == "0.500"
    def test_curr_set_negative_fails(self, psu: PowerSupplySim) -> None:
        """Test CURR rejects negative values."""
        response = psu.process("CURR -1.0")
        assert response.startswith("ERROR:")
        assert "negative" in response
    def test_curr_set_invalid_value(self, psu: PowerSupplySim) -> None:
        """Test CURR with invalid value returns error."""
        response = psu.process("CURR xyz")
        assert response.startswith("ERROR:")
        assert "Invalid current" in response
    def test_curr_set_no_argument(self, psu: PowerSupplySim) -> None:
        """Test CURR without argument returns error."""
        response = psu.process("CURR")
        assert response.startswith("ERROR:")
        assert "requires a value" in response
 class TestPowerSupplyOutput:
    """Tests for OUTP command."""
    @pytest.fixture
    def psu(self) -> PowerSupplySim:
        """Create power supply instance without physics engine."""
        return PowerSupplySim()
    def test_outp_query_default(self, psu: PowerSupplySim) -> None:
        """Test OUTP? returns default value (off)."""
        response = psu.process("OUTP?")
        assert response == "0"
    def test_outp_set_on(self, psu: PowerSupplySim) -> None:
        """Test OUTP ON enables output."""
        response = psu.process("OUTP ON")
        assert response == ""
        assert psu.process("OUTP?") == "1"
    def test_outp_set_1(self, psu: PowerSupplySim) -> None:
        """Test OUTP 1 enables output."""
        psu.process("OUTP 1")
        assert psu.process("OUTP?") == "1"
    def test_outp_set_off(self, psu: PowerSupplySim) -> None:
        """Test OUTP OFF disables output."""
        psu.process("OUTP ON")
        psu.process("OUTP OFF")
        assert psu.process("OUTP?") == "0"
    def test_outp_set_0(self, psu: PowerSupplySim) -> None:
        """Test OUTP 0 disables output."""
        psu.process("OUTP ON")
        psu.process("OUTP 0")
        assert psu.process("OUTP?") == "0"
    def test_outp_set_invalid(self, psu: PowerSupplySim) -> None:
        """Test OUTP with invalid value returns error."""
        response = psu.process("OUTP MAYBE")
        assert response.startswith("ERROR:")
        assert "Invalid output state" in response
    def test_outp_set_no_argument(self, psu: PowerSupplySim) -> None:
        """Test OUTP without argument returns error."""
        response = psu.process("OUTP")
        assert response.startswith("ERROR:")
        assert "requires a value" in response
 class TestPowerSupplyMeasurement:
    """Tests for MEAS commands."""
    @pytest.fixture
    def psu(self) -> PowerSupplySim:
        """Create power supply instance without physics engine."""
        return PowerSupplySim()
    def test_meas_volt_when_off(self, psu: PowerSupplySim) -> None:
        """Test MEAS:VOLT? returns 0 when output is off."""
        psu.process("VOLT 12.0")
        response = psu.process("MEAS:VOLT?")
        assert response == "0.000"
    def test_meas_volt_when_on_no_engine(self, psu: PowerSupplySim) -> None:
        """Test MEAS:VOLT? returns setpoint when on without engine."""
        psu.process("VOLT 12.0")
        psu.process("OUTP ON")
        response = psu.process("MEAS:VOLT?")
        assert response == "12.000"
    def test_meas_volt_as_command_fails(self, psu: PowerSupplySim) -> None:
        """Test MEAS:VOLT (without ?) returns error."""
        response = psu.process("MEAS:VOLT 5.0")
        assert response.startswith("ERROR:")
        assert "query only" in response
    def test_meas_curr_when_off(self, psu: PowerSupplySim) -> None:
        """Test MEAS:CURR? returns 0 when output is off."""
        response = psu.process("MEAS:CURR?")
        assert response == "0.000"
    def test_meas_curr_when_on_no_engine(self, psu: PowerSupplySim) -> None:
        """Test MEAS:CURR? returns 0 when on without engine."""
        psu.process("OUTP ON")
        response = psu.process("MEAS:CURR?")
        assert response == "0.000"
    def test_meas_curr_as_command_fails(self, psu: PowerSupplySim) -> None:
        """Test MEAS:CURR (without ?) returns error."""
        response = psu.process("MEAS:CURR 0.1")
        assert response.startswith("ERROR:")
        assert "query only" in response
 class TestPowerSupplyWithPhysicsEngine:
    """Tests for PowerSupplySim with physics engine integration."""
    @pytest.fixture
    def engine(self) -> PhysicsEngine:
        """Create physics engine instance."""
        return PhysicsEngine(update_rate_hz=100.0)
    @pytest.fixture
    def psu(self, engine: PhysicsEngine) -> PowerSupplySim:
        """Create power supply instance with physics engine."""
        return PowerSupplySim(physics_engine=engine)
    def test_outp_on_enables_engine_output(
        self, psu: PowerSupplySim, engine: PhysicsEngine
    ) -> None:
        """Test OUTP ON enables physics engine output."""
        psu.process("VOLT 5.0")
        psu.process("OUTP ON")
        assert engine.is_output_enabled is True
    def test_outp_off_disables_engine_output(
        self, psu: PowerSupplySim, engine: PhysicsEngine
    ) -> None:
        """Test OUTP OFF disables physics engine output."""
        psu.process("OUTP ON")
        psu.process("OUTP OFF")
        assert engine.is_output_enabled is False
    def test_volt_updates_engine_when_on(
        self, psu: PowerSupplySim, engine: PhysicsEngine
    ) -> None:
        """Test VOLT updates engine input voltage when output is on."""
        psu.process("OUTP ON")
        psu.process("VOLT 5.0")
        electrical = engine.get_electrical_state()
        assert electrical.input_voltage == pytest.approx(5.0)
    def test_volt_does_not_update_engine_when_off(
        self, psu: PowerSupplySim, engine: PhysicsEngine
    ) -> None:
        """Test VOLT does not update engine when output is off."""
        psu.process("VOLT 5.0")
        electrical = engine.get_electrical_state()
        assert electrical.input_voltage == pytest.approx(0.0)
    def test_meas_volt_returns_engine_voltage(
        self, psu: PowerSupplySim, engine: PhysicsEngine
    ) -> None:
        """Test MEAS:VOLT? returns physics engine voltage."""
        psu.process("VOLT 5.0")
        psu.process("OUTP ON")
        response = psu.process("MEAS:VOLT?")
        assert response == "5.000"
    def test_meas_curr_returns_engine_current(
        self, psu: PowerSupplySim, engine: PhysicsEngine
    ) -> None:
        """Test MEAS:CURR? returns total current from engine."""
        psu.process("VOLT 5.0")
        psu.process("OUTP ON")
        engine.set_load_current(0.1)
        # Step engine to allow calculations
        engine.step()
        response = psu.process("MEAS:CURR?")
        # Should include load current + quiescent current
        assert float(response) > 0.0
    def test_reset_disables_engine_output(
        self, psu: PowerSupplySim, engine: PhysicsEngine
    ) -> None:
        """Test *RST disables physics engine output."""
        psu.process("VOLT 5.0")
        psu.process("OUTP ON")
        psu.process("*RST")
        assert engine.is_output_enabled is False
    def test_reset_sets_engine_voltage_zero(
        self, psu: PowerSupplySim, engine: PhysicsEngine
    ) -> None:
        """Test *RST sets physics engine voltage to zero."""
        psu.process("VOLT 5.0")
        psu.process("OUTP ON")
        psu.process("*RST")
        electrical = engine.get_electrical_state()
        assert electrical.input_voltage == pytest.approx(0.0)
--- a/tests/unit/test_repository.py
+++ b/tests/unit/test_repository.py
@@ -0,0 +1,295 @@
 """Unit tests for data repository."""
 import tempfile
 from pathlib import Path
 from uuid import uuid4
 import pandas as pd
 import pytest
 from py_dvt_ate.data.models import Measurement, TestStatus
 from py_dvt_ate.data.repository import SQLiteRepository
@pytest.fixture
 def temp_db():
    """Create a temporary database for testing."""
    with tempfile.TemporaryDirectory() as tmpdir:
        db_path = Path(tmpdir) / "test.db"
        yield db_path
@pytest.fixture
 def repository(temp_db):
    """Create a repository instance for testing."""
    return SQLiteRepository(temp_db)
 def test_create_run(repository):
    """Test creating a new test run."""
    config = {"temperature": 25.0, "voltage": 3.3}
    run_id = repository.create_run(
        test_name="TempCo Test",
        config=config,
        operator="Test Engineer",
        description="Test description",
    )
    assert run_id is not None
    # Verify run was created
    run = repository.get_run(run_id)
    assert run.test_name == "TempCo Test"
    assert run.operator == "Test Engineer"
    assert run.description == "Test description"
    assert run.status == TestStatus.PENDING
 def test_update_run_status(repository):
    """Test updating test run status."""
    run_id = repository.create_run("Test", config={})
    repository.update_run_status(run_id, TestStatus.RUNNING)
    run = repository.get_run(run_id)
    assert run.status == TestStatus.RUNNING
    repository.update_run_status(run_id, TestStatus.PASSED)
    run = repository.get_run(run_id)
    assert run.status == TestStatus.PASSED
 def test_complete_run(repository):
    """Test completing a test run."""
    run_id = repository.create_run("Test", config={})
    repository.complete_run(run_id, TestStatus.PASSED)
    run = repository.get_run(run_id)
    assert run.status == TestStatus.PASSED
    assert run.completed_at is not None
 def test_save_result(repository):
    """Test saving a test result."""
    run_id = repository.create_run("Test", config={})
    repository.save_result(
        run_id=run_id,
        parameter="output_voltage",
        value=3.305,
        unit="V",
        lower_limit=3.267,
        upper_limit=3.333,
    )
    results = repository.get_results(run_id)
    assert len(results) == 1
    result = results[0]
    assert result.parameter == "output_voltage"
    assert result.value == 3.305
    assert result.unit == "V"
    assert result.lower_limit == 3.267
    assert result.upper_limit == 3.333
    assert result.passed is True
 def test_save_result_fail(repository):
    """Test saving a failing test result."""
    run_id = repository.create_run("Test", config={})
    repository.save_result(
        run_id=run_id,
        parameter="output_voltage",
        value=3.350,  # Outside upper limit
        unit="V",
        lower_limit=3.267,
        upper_limit=3.333,
    )
    results = repository.get_results(run_id)
    result = results[0]
    assert result.passed is False
 def test_save_result_no_limits(repository):
    """Test saving a result without limits."""
    run_id = repository.create_run("Test", config={})
    repository.save_result(
        run_id=run_id,
        parameter="temperature",
        value=25.5,
        unit="°C",
    )
    results = repository.get_results(run_id)
    result = results[0]
    assert result.passed is None  # No limits defined
 def test_save_measurements(repository):
    """Test saving time-series measurements to Parquet."""
    run_id = repository.create_run("Test", config={})
    measurements = [
        Measurement(
            timestamp=1234567890.0,
            parameter="voltage",
            value=3.3,
            unit="V",
            temperature=25.0,
            input_voltage=5.0,
            load_current=0.1,
        ),
        Measurement(
            timestamp=1234567891.0,
            parameter="voltage",
            value=3.31,
            unit="V",
            temperature=25.1,
            input_voltage=5.0,
            load_current=0.1,
        ),
    ]
    repository.save_measurements(run_id, measurements)
    # Verify measurements were saved
    df = repository.get_measurements_dataframe(run_id)
    assert df is not None
    assert len(df) == 2
    assert list(df["parameter"]) == ["voltage", "voltage"]
    assert list(df["value"]) == [3.3, 3.31]
 def test_save_measurements_append(repository):
    """Test appending measurements to existing Parquet file."""
    run_id = repository.create_run("Test", config={})
    # Save first batch
    measurements1 = [
        Measurement(
            timestamp=1234567890.0,
            parameter="voltage",
            value=3.3,
            unit="V",
        )
    ]
    repository.save_measurements(run_id, measurements1)
    # Save second batch
    measurements2 = [
        Measurement(
            timestamp=1234567891.0,
            parameter="voltage",
            value=3.31,
            unit="V",
        )
    ]
    repository.save_measurements(run_id, measurements2)
    # Verify both batches are present
    df = repository.get_measurements_dataframe(run_id)
    assert df is not None
    assert len(df) == 2
 def test_get_measurements_nonexistent(repository):
    """Test getting measurements for non-existent run."""
    fake_id = uuid4()
    df = repository.get_measurements_dataframe(fake_id)
    assert df is None
 def test_save_empty_measurements(repository):
    """Test saving empty measurement list."""
    run_id = repository.create_run("Test", config={})
    repository.save_measurements(run_id, [])
    df = repository.get_measurements_dataframe(run_id)
    assert df is None
 def test_get_nonexistent_run(repository):
    """Test getting a non-existent run raises error."""
    fake_id = uuid4()
    with pytest.raises(ValueError, match="not found"):
        repository.get_run(fake_id)
 def test_multiple_results(repository):
    """Test saving and retrieving multiple results."""
    run_id = repository.create_run("Test", config={})
    repository.save_result(run_id, "voltage", 3.3, "V")
    repository.save_result(run_id, "current", 50.0, "uA")
    repository.save_result(run_id, "temperature", 25.0, "°C")
    results = repository.get_results(run_id)
    assert len(results) == 3
    parameters = {r.parameter for r in results}
    assert parameters == {"voltage", "current", "temperature"}
 def test_custom_measurements_dir(temp_db):
    """Test using a custom measurements directory."""
    with tempfile.TemporaryDirectory() as tmpdir:
        measurements_dir = Path(tmpdir) / "custom_measurements"
        repo = SQLiteRepository(temp_db, measurements_dir=measurements_dir)
        run_id = repo.create_run("Test", config={})
        measurements = [
            Measurement(
                timestamp=1234567890.0,
                parameter="voltage",
                value=3.3,
                unit="V",
            )
        ]
        repo.save_measurements(run_id, measurements)
        # Verify file is in custom directory
        expected_path = measurements_dir / f"run_{run_id}" / "measurements.parquet"
        assert expected_path.exists()
 def test_parquet_schema(repository):
    """Test that Parquet file has correct schema."""
    run_id = repository.create_run("Test", config={})
    measurements = [
        Measurement(
            timestamp=1234567890.123,
            parameter="voltage",
            value=3.3,
            unit="V",
            temperature=25.5,
            input_voltage=5.0,
            load_current=0.1,
        )
    ]
    repository.save_measurements(run_id, measurements)
    df = repository.get_measurements_dataframe(run_id)
    assert df is not None
    # Check columns
    expected_columns = {
        "timestamp",
        "parameter",
        "value",
        "unit",
        "temperature",
        "input_voltage",
        "load_current",
    }
    assert set(df.columns) == expected_columns
    # Check data types (approximately)
    assert pd.api.types.is_float_dtype(df["timestamp"])
    assert pd.api.types.is_string_dtype(df["parameter"]) or pd.api.types.is_object_dtype(
        df["parameter"]
    )
    assert pd.api.types.is_float_dtype(df["value"])
--- a/tests/unit/test_scpi_parser.py
+++ b/tests/unit/test_scpi_parser.py
@@ -0,0 +1,203 @@
 """Unit tests for SCPI command parsing."""
 import pytest
 from py_dvt_ate.instruments.scpi import SCPICommand, SCPIParser
 class TestSCPICommand:
    """Tests for the SCPICommand dataclass."""
    def test_creation(self) -> None:
        """Test SCPICommand can be created with valid values."""
        cmd = SCPICommand(
            header="VOLT",
            arguments=["3.3"],
            is_query=False,
        )
        assert cmd.header == "VOLT"
        assert cmd.arguments == ["3.3"]
        assert cmd.is_query is False
    def test_keyword_for_command(self) -> None:
        """Test keyword property for regular command."""
        cmd = SCPICommand(header="VOLT", arguments=["3.3"], is_query=False)
        assert cmd.keyword == "VOLT"
    def test_keyword_for_query(self) -> None:
        """Test keyword property strips '?' from query."""
        cmd = SCPICommand(header="VOLT?", arguments=[], is_query=True)
        assert cmd.keyword == "VOLT"
    def test_keyword_for_nested_command(self) -> None:
        """Test keyword property for nested SCPI command."""
        cmd = SCPICommand(header="TEMP:SETPOINT?", arguments=[], is_query=True)
        assert cmd.keyword == "TEMP:SETPOINT"
 class TestSCPIParser:
    """Tests for the SCPIParser class."""
    @pytest.fixture
    def parser(self) -> SCPIParser:
        """Create parser instance for tests."""
        return SCPIParser()
    def test_parse_simple_query(self, parser: SCPIParser) -> None:
        """Test parsing simple query command."""
        cmd = parser.parse("*IDN?")
        assert cmd.header == "*IDN?"
        assert cmd.arguments == []
        assert cmd.is_query is True
        assert cmd.keyword == "*IDN"
    def test_parse_simple_command(self, parser: SCPIParser) -> None:
        """Test parsing simple command without arguments."""
        cmd = parser.parse("*RST")
        assert cmd.header == "*RST"
        assert cmd.arguments == []
        assert cmd.is_query is False
        assert cmd.keyword == "*RST"
    def test_parse_command_with_single_argument(self, parser: SCPIParser) -> None:
        """Test parsing command with single numeric argument."""
        cmd = parser.parse("VOLT 3.3")
        assert cmd.header == "VOLT"
        assert cmd.arguments == ["3.3"]
        assert cmd.is_query is False
    def test_parse_command_with_multiple_arguments(self, parser: SCPIParser) -> None:
        """Test parsing command with comma-separated arguments."""
        cmd = parser.parse("CONF:VOLT:DC 10,0.001")
        assert cmd.header == "CONF:VOLT:DC"
        assert cmd.arguments == ["10", "0.001"]
        assert cmd.is_query is False
    def test_parse_nested_scpi_command(self, parser: SCPIParser) -> None:
        """Test parsing nested SCPI command hierarchy."""
        cmd = parser.parse("TEMP:SETPOINT 85.0")
        assert cmd.header == "TEMP:SETPOINT"
        assert cmd.arguments == ["85.0"]
        assert cmd.is_query is False
        assert cmd.keyword == "TEMP:SETPOINT"
    def test_parse_nested_scpi_query(self, parser: SCPIParser) -> None:
        """Test parsing nested SCPI query."""
        cmd = parser.parse("TEMP:SETPOINT?")
        assert cmd.header == "TEMP:SETPOINT?"
        assert cmd.arguments == []
        assert cmd.is_query is True
    def test_parse_ieee_common_commands(self, parser: SCPIParser) -> None:
        """Test parsing IEEE 488.2 common commands."""
        # Identity query
        cmd = parser.parse("*IDN?")
        assert cmd.is_query is True
        assert cmd.keyword == "*IDN"
        # Reset
        cmd = parser.parse("*RST")
        assert cmd.is_query is False
        assert cmd.keyword == "*RST"
        # Clear status
        cmd = parser.parse("*CLS")
        assert cmd.is_query is False
        assert cmd.keyword == "*CLS"
        # Operation complete query
        cmd = parser.parse("*OPC?")
        assert cmd.is_query is True
        assert cmd.keyword == "*OPC"
    def test_parse_strips_whitespace(self, parser: SCPIParser) -> None:
        """Test parser strips leading and trailing whitespace."""
        cmd = parser.parse("  VOLT 3.3  ")
        assert cmd.header == "VOLT"
        assert cmd.arguments == ["3.3"]
    def test_parse_strips_argument_whitespace(self, parser: SCPIParser) -> None:
        """Test parser strips whitespace from arguments."""
        cmd = parser.parse("CONF:VOLT:DC  10 , 0.001 ")
        assert cmd.arguments == ["10", "0.001"]
    def test_parse_empty_string(self, parser: SCPIParser) -> None:
        """Test parsing empty string returns empty command."""
        cmd = parser.parse("")
        assert cmd.header == ""
        assert cmd.arguments == []
        assert cmd.is_query is False
    def test_parse_whitespace_only(self, parser: SCPIParser) -> None:
        """Test parsing whitespace-only string returns empty command."""
        cmd = parser.parse("   ")
        assert cmd.header == ""
        assert cmd.arguments == []
        assert cmd.is_query is False
    def test_parse_output_on_off(self, parser: SCPIParser) -> None:
        """Test parsing output enable/disable commands."""
        cmd_on = parser.parse("OUTP ON")
        assert cmd_on.arguments == ["ON"]
        cmd_off = parser.parse("OUTP OFF")
        assert cmd_off.arguments == ["OFF"]
        cmd_1 = parser.parse("OUTP 1")
        assert cmd_1.arguments == ["1"]
        cmd_0 = parser.parse("OUTP 0")
        assert cmd_0.arguments == ["0"]
    def test_parse_channel_select(self, parser: SCPIParser) -> None:
        """Test parsing channel selection commands."""
        cmd = parser.parse("INST:SEL CH1")
        assert cmd.header == "INST:SEL"
        assert cmd.arguments == ["CH1"]
    def test_parse_measurement_query(self, parser: SCPIParser) -> None:
        """Test parsing measurement query commands."""
        cmd = parser.parse("MEAS:VOLT:DC?")
        assert cmd.header == "MEAS:VOLT:DC?"
        assert cmd.is_query is True
        assert cmd.keyword == "MEAS:VOLT:DC"
    def test_parse_measurement_with_range(self, parser: SCPIParser) -> None:
        """Test parsing measurement query with range argument."""
        cmd = parser.parse("MEAS:VOLT:DC? AUTO")
        assert cmd.header == "MEAS:VOLT:DC?"
        assert cmd.arguments == ["AUTO"]
        assert cmd.is_query is True
    def test_parse_system_error_query(self, parser: SCPIParser) -> None:
        """Test parsing system error query."""
        cmd = parser.parse("SYST:ERR?")
        assert cmd.header == "SYST:ERR?"
        assert cmd.is_query is True
        assert cmd.keyword == "SYST:ERR"
    def test_parse_nplc_setting(self, parser: SCPIParser) -> None:
        """Test parsing NPLC (integration time) command."""
        cmd = parser.parse("SENS:VOLT:DC:NPLC 10")
        assert cmd.header == "SENS:VOLT:DC:NPLC"
        assert cmd.arguments == ["10"]
        assert cmd.is_query is False
--- a/tests/unit/test_thermal_chamber.py
+++ b/tests/unit/test_thermal_chamber.py
@@ -0,0 +1,215 @@
 """Unit tests for thermal chamber simulator."""
 import pytest
 from py_dvt_ate.simulation.physics.engine import PhysicsEngine
 from py_dvt_ate.simulation.virtual.chamber import ThermalChamberSim
 class TestThermalChamberSimBasic:
    """Tests for ThermalChamberSim without physics engine."""
    @pytest.fixture
    def chamber(self) -> ThermalChamberSim:
        """Create chamber instance without physics engine."""
        return ThermalChamberSim()
    def test_creation(self, chamber: ThermalChamberSim) -> None:
        """Test chamber can be created."""
        assert chamber is not None
        assert chamber.model == "TC-SIM-001"
        assert chamber.manufacturer == "PyDVTATE"
    def test_idn_query(self, chamber: ThermalChamberSim) -> None:
        """Test *IDN? returns identification string."""
        response = chamber.process("*IDN?")
        assert "PyDVTATE" in response
        assert "TC-SIM-001" in response
    def test_rst_command(self, chamber: ThermalChamberSim) -> None:
        """Test *RST resets to defaults."""
        # Set non-default value
        chamber.process("TEMP:SETPOINT 85.0")
        assert chamber.process("TEMP:SETPOINT?") == "85.00"
        # Reset
        response = chamber.process("*RST")
        assert response == ""
        assert chamber.process("TEMP:SETPOINT?") == "25.00"
    def test_opc_query(self, chamber: ThermalChamberSim) -> None:
        """Test *OPC? returns 1."""
        response = chamber.process("*OPC?")
        assert response == "1"
    def test_unknown_command(self, chamber: ThermalChamberSim) -> None:
        """Test unknown command returns error."""
        response = chamber.process("INVALID:CMD")
        assert response.startswith("ERROR:")
        assert "Unknown command" in response
 class TestThermalChamberSetpoint:
    """Tests for TEMP:SETPOINT command."""
    @pytest.fixture
    def chamber(self) -> ThermalChamberSim:
        """Create chamber instance without physics engine."""
        return ThermalChamberSim()
    def test_setpoint_query_default(self, chamber: ThermalChamberSim) -> None:
        """Test TEMP:SETPOINT? returns default value."""
        response = chamber.process("TEMP:SETPOINT?")
        assert response == "25.00"
    def test_setpoint_set(self, chamber: ThermalChamberSim) -> None:
        """Test TEMP:SETPOINT sets value."""
        response = chamber.process("TEMP:SETPOINT 85.0")
        assert response == ""
        assert chamber.process("TEMP:SETPOINT?") == "85.00"
    def test_setpoint_set_negative(self, chamber: ThermalChamberSim) -> None:
        """Test TEMP:SETPOINT accepts negative values."""
        chamber.process("TEMP:SETPOINT -40.0")
        assert chamber.process("TEMP:SETPOINT?") == "-40.00"
    def test_setpoint_set_invalid_value(self, chamber: ThermalChamberSim) -> None:
        """Test TEMP:SETPOINT with invalid value returns error."""
        response = chamber.process("TEMP:SETPOINT abc")
        assert response.startswith("ERROR:")
        assert "Invalid temperature" in response
    def test_setpoint_set_no_argument(self, chamber: ThermalChamberSim) -> None:
        """Test TEMP:SETPOINT without argument returns error."""
        response = chamber.process("TEMP:SETPOINT")
        assert response.startswith("ERROR:")
        assert "requires a value" in response
 class TestThermalChamberActual:
    """Tests for TEMP:ACTUAL? query."""
    @pytest.fixture
    def chamber(self) -> ThermalChamberSim:
        """Create chamber instance without physics engine."""
        return ThermalChamberSim()
    def test_actual_query_without_engine(self, chamber: ThermalChamberSim) -> None:
        """Test TEMP:ACTUAL? returns setpoint when no physics engine."""
        chamber.process("TEMP:SETPOINT 50.0")
        response = chamber.process("TEMP:ACTUAL?")
        # Without physics engine, returns setpoint
        assert response == "50.00"
    def test_actual_as_command_fails(self, chamber: ThermalChamberSim) -> None:
        """Test TEMP:ACTUAL (without ?) returns error."""
        response = chamber.process("TEMP:ACTUAL 25.0")
        assert response.startswith("ERROR:")
        assert "query only" in response
 class TestThermalChamberStability:
    """Tests for TEMP:STAB? query."""
    @pytest.fixture
    def chamber(self) -> ThermalChamberSim:
        """Create chamber instance without physics engine."""
        return ThermalChamberSim()
    def test_stab_query_without_engine(self, chamber: ThermalChamberSim) -> None:
        """Test TEMP:STAB? returns 1 when no physics engine."""
        response = chamber.process("TEMP:STAB?")
        # Without physics engine, assume stable
        assert response == "1"
    def test_stab_as_command_fails(self, chamber: ThermalChamberSim) -> None:
        """Test TEMP:STAB (without ?) returns error."""
        response = chamber.process("TEMP:STAB 1")
        assert response.startswith("ERROR:")
        assert "query only" in response
 class TestThermalChamberWithPhysicsEngine:
    """Tests for ThermalChamberSim with physics engine integration."""
    @pytest.fixture
    def engine(self) -> PhysicsEngine:
        """Create physics engine instance."""
        return PhysicsEngine(update_rate_hz=100.0)
    @pytest.fixture
    def chamber(self, engine: PhysicsEngine) -> ThermalChamberSim:
        """Create chamber instance with physics engine."""
        return ThermalChamberSim(physics_engine=engine)
    def test_setpoint_updates_engine(
        self, chamber: ThermalChamberSim, engine: PhysicsEngine
    ) -> None:
        """Test TEMP:SETPOINT updates physics engine."""
        chamber.process("TEMP:SETPOINT 85.0")
        # Step the engine and check thermal state
        thermal = engine.get_thermal_state()
        # Initial chamber temp is 25, will start moving towards 85
        assert thermal.chamber_temperature == pytest.approx(25.0, abs=0.1)
        # After many steps, should approach setpoint
        for _ in range(10000):  # 100 seconds at 100Hz
            engine.step()
        thermal = engine.get_thermal_state()
        # Should be closer to setpoint (but not quite there due to time constant)
        assert thermal.chamber_temperature > 80.0
    def test_actual_query_returns_engine_temperature(
        self, chamber: ThermalChamberSim, engine: PhysicsEngine
    ) -> None:
        """Test TEMP:ACTUAL? returns physics engine temperature."""
        response = chamber.process("TEMP:ACTUAL?")
        # Should match initial chamber temperature
        assert response == "25.00"
    def test_stability_when_at_setpoint(
        self, chamber: ThermalChamberSim, engine: PhysicsEngine
    ) -> None:
        """Test TEMP:STAB? returns 1 when at setpoint."""
        # Default setpoint is 25, engine starts at 25
        response = chamber.process("TEMP:STAB?")
        assert response == "1"
    def test_stability_when_settling(
        self, chamber: ThermalChamberSim, engine: PhysicsEngine
    ) -> None:
        """Test TEMP:STAB? returns 0 when settling."""
        # Set new setpoint far from current temperature
        chamber.process("TEMP:SETPOINT 85.0")
        # Step once to ensure engine updates
        engine.step()
        # Should not be stable yet
        response = chamber.process("TEMP:STAB?")
        assert response == "0"
    def test_reset_updates_engine(
        self, chamber: ThermalChamberSim, engine: PhysicsEngine
    ) -> None:
        """Test *RST resets both chamber and engine setpoint."""
        chamber.process("TEMP:SETPOINT 85.0")
        chamber.process("*RST")
        # Check setpoint is back to default
        assert chamber.process("TEMP:SETPOINT?") == "25.00"
--- a/tests/unit/test_transport.py
+++ b/tests/unit/test_transport.py
@@ -0,0 +1,263 @@
 """Unit tests for transport layer."""
 import socket
 from unittest.mock import MagicMock, Mock, patch
 import pytest
 from py_dvt_ate.instruments.transport.tcp import TCPTransport
 class TestTCPTransport:
    """Tests for TCPTransport class."""
    @pytest.fixture
    def transport(self) -> TCPTransport:
        """Create transport instance for tests."""
        return TCPTransport("localhost", 5025, timeout=1.0)
    def test_creation(self, transport: TCPTransport) -> None:
        """Test TCPTransport can be created with valid parameters."""
        assert transport.host == "localhost"
        assert transport.port == 5025
        assert not transport.is_connected
    def test_repr(self, transport: TCPTransport) -> None:
        """Test string representation."""
        assert "localhost:5025" in repr(transport)
        assert "disconnected" in repr(transport)
    @patch("socket.socket")
    def test_connect_success(
        self, mock_socket_class: Mock, transport: TCPTransport
    ) -> None:
        """Test successful connection."""
        mock_sock = MagicMock()
        mock_socket_class.return_value = mock_sock
        transport.connect()
        assert transport.is_connected
        mock_socket_class.assert_called_once_with(
            socket.AF_INET, socket.SOCK_STREAM
        )
        mock_sock.settimeout.assert_called_once_with(1.0)
        mock_sock.connect.assert_called_once_with(("localhost", 5025))
    @patch("socket.socket")
    def test_connect_already_connected(
        self, mock_socket_class: Mock, transport: TCPTransport
    ) -> None:
        """Test connecting when already connected raises error."""
        mock_sock = MagicMock()
        mock_socket_class.return_value = mock_sock
        transport.connect()
        with pytest.raises(ConnectionError, match="Already connected"):
            transport.connect()
    @patch("socket.socket")
    def test_connect_failure(
        self, mock_socket_class: Mock, transport: TCPTransport
    ) -> None:
        """Test connection failure raises ConnectionError."""
        mock_sock = MagicMock()
        mock_socket_class.return_value = mock_sock
        mock_sock.connect.side_effect = OSError("Connection refused")
        with pytest.raises(ConnectionError, match="Failed to connect"):
            transport.connect()
        assert not transport.is_connected
    @patch("socket.socket")
    def test_disconnect(
        self, mock_socket_class: Mock, transport: TCPTransport
    ) -> None:
        """Test disconnect closes socket."""
        mock_sock = MagicMock()
        mock_socket_class.return_value = mock_sock
        transport.connect()
        transport.disconnect()
        mock_sock.close.assert_called_once()
        assert not transport.is_connected
    def test_disconnect_when_not_connected(self, transport: TCPTransport) -> None:
        """Test disconnect is idempotent."""
        transport.disconnect()  # Should not raise
        assert not transport.is_connected
    @patch("socket.socket")
    def test_write(self, mock_socket_class: Mock, transport: TCPTransport) -> None:
        """Test write sends command with newline."""
        mock_sock = MagicMock()
        mock_socket_class.return_value = mock_sock
        transport.connect()
        transport.write("*IDN?")
        mock_sock.sendall.assert_called_once_with(b"*IDN?\n")
    def test_write_not_connected(self, transport: TCPTransport) -> None:
        """Test write when not connected raises error."""
        with pytest.raises(ConnectionError, match="Not connected"):
            transport.write("*IDN?")
    @patch("socket.socket")
    def test_write_failure(
        self, mock_socket_class: Mock, transport: TCPTransport
    ) -> None:
        """Test write failure raises IOError."""
        mock_sock = MagicMock()
        mock_socket_class.return_value = mock_sock
        mock_sock.sendall.side_effect = OSError("Write failed")
        transport.connect()
        with pytest.raises(OSError, match="Write failed"):
            transport.write("*IDN?")
    @patch("socket.socket")
    def test_read(self, mock_socket_class: Mock, transport: TCPTransport) -> None:
        """Test read receives response until newline."""
        mock_sock = MagicMock()
        mock_socket_class.return_value = mock_sock
        # Simulate receiving "OK\n" byte by byte
        mock_sock.recv.side_effect = [b"O", b"K", b"\n"]
        transport.connect()
        response = transport.read()
        assert response == "OK"
    @patch("socket.socket")
    def test_read_with_timeout(
        self, mock_socket_class: Mock, transport: TCPTransport
    ) -> None:
        """Test read with custom timeout."""
        mock_sock = MagicMock()
        mock_socket_class.return_value = mock_sock
        mock_sock.gettimeout.return_value = 1.0
        # Simulate receiving "OK\n"
        mock_sock.recv.side_effect = [b"O", b"K", b"\n"]
        transport.connect()
        response = transport.read(timeout=2.0)
        assert response == "OK"
        # Verify timeout was changed and restored
        assert mock_sock.settimeout.call_count == 3  # connect + custom + restore
        mock_sock.settimeout.assert_any_call(2.0)
        mock_sock.settimeout.assert_any_call(1.0)
    def test_read_not_connected(self, transport: TCPTransport) -> None:
        """Test read when not connected raises error."""
        with pytest.raises(ConnectionError, match="Not connected"):
            transport.read()
    @patch("socket.socket")
    def test_read_timeout(
        self, mock_socket_class: Mock, transport: TCPTransport
    ) -> None:
        """Test read timeout raises TimeoutError."""
        mock_sock = MagicMock()
        mock_socket_class.return_value = mock_sock
        mock_sock.recv.side_effect = TimeoutError("Timed out")
        transport.connect()
        with pytest.raises(TimeoutError, match="Read timeout"):
            transport.read()
    @patch("socket.socket")
    def test_read_connection_closed(
        self, mock_socket_class: Mock, transport: TCPTransport
    ) -> None:
        """Test read when connection closed raises error."""
        mock_sock = MagicMock()
        mock_socket_class.return_value = mock_sock
        mock_sock.recv.return_value = b""  # Empty means connection closed
        transport.connect()
        with pytest.raises(ConnectionError, match="Connection closed"):
            transport.read()
    @patch("socket.socket")
    def test_query(self, mock_socket_class: Mock, transport: TCPTransport) -> None:
        """Test query combines write and read."""
        mock_sock = MagicMock()
        mock_socket_class.return_value = mock_sock
        # Simulate receiving "Test Device\n"
        mock_sock.recv.side_effect = [
            b"T",
            b"e",
            b"s",
            b"t",
            b" ",
            b"D",
            b"e",
            b"v",
            b"i",
            b"c",
            b"e",
            b"\n",
        ]
        transport.connect()
        response = transport.query("*IDN?")
        assert response == "Test Device"
        mock_sock.sendall.assert_called_once_with(b"*IDN?\n")
    @patch("socket.socket")
    def test_query_with_timeout(
        self, mock_socket_class: Mock, transport: TCPTransport
    ) -> None:
        """Test query with custom timeout."""
        mock_sock = MagicMock()
        mock_socket_class.return_value = mock_sock
        mock_sock.gettimeout.return_value = 1.0
        mock_sock.recv.side_effect = [b"O", b"K", b"\n"]
        transport.connect()
        response = transport.query("*IDN?", timeout=3.0)
        assert response == "OK"
        mock_sock.settimeout.assert_any_call(3.0)
    @patch("socket.socket")
    def test_context_manager(
        self, mock_socket_class: Mock, transport: TCPTransport
    ) -> None:
        """Test context manager connects and disconnects."""
        mock_sock = MagicMock()
        mock_socket_class.return_value = mock_sock
        with transport:
            assert transport.is_connected
        mock_sock.close.assert_called_once()
        assert not transport.is_connected
    @patch("socket.socket")
    def test_context_manager_with_exception(
        self, mock_socket_class: Mock, transport: TCPTransport
    ) -> None:
        """Test context manager disconnects even on exception."""
        mock_sock = MagicMock()
        mock_socket_class.return_value = mock_sock
        with pytest.raises(ValueError):
            with transport:
                raise ValueError("Test error")
        mock_sock.close.assert_called_once()
        assert not transport.is_connected
Author	SHA1	Message	Date
Kai Chappell	2e62a10550	Release v0.1.0-beta.2 Some checks failed CI / Lint (push) Failing after 4s Details CI / Type Check (push) Successful in 18s Details CI / Test (push) Failing after 20s Details CI / Release (push) Has been cancelled Details	2025-09-22 11:04:43 +00:00
Kai Chappell	d07e6e3f1a	Add TempCo integration tests	2025-09-16 11:20:03 +00:00
Kai Chappell	96eb83cec4	Implement TempCo characterisation test	2025-09-15 18:32:58 +00:00
Kai Chappell	027fd71505	Add DVT test base class	2025-09-10 16:03:37 +00:00
Kai Chappell	3310e86fae	Implement test runner	2025-09-09 19:31:09 +00:00
Kai Chappell	e42de212f2	Implement limit checker	2025-09-05 15:44:46 +00:00
Kai Chappell	ee8d148eb7	Implement test logger	2025-08-31 17:24:16 +00:00
Kai Chappell	e379b7e432	Add test framework models	2025-08-28 21:57:03 +00:00
Kai Chappell	eaa1843ee1	Add data persistence tests	2025-08-25 14:31:30 +00:00
Kai Chappell	7429f6433c	Add Parquet measurement storage	2025-08-20 23:59:48 +00:00
Kai Chappell	7cfd36f02b	Implement SQLite repository	2025-08-17 20:54:35 +00:00
Kai Chappell	f5600efd76	Add data persistence models	2025-08-17 11:34:53 +00:00
Kai Chappell	0615eb7e07	Add configuration tests	2025-08-14 15:59:04 +00:00
Kai Chappell	b981182b71	Add default configuration file	2025-08-11 13:11:17 +00:00
Kai Chappell	8c0d68e722	Implement configuration loader	2025-08-05 15:12:34 +00:00
Kai Chappell	4e14222522	Add configuration Pydantic models	2025-08-01 17:46:03 +00:00
Kai Chappell	afa52e7ee2	Release v0.1.0-beta.1 Some checks failed CI / Lint (push) Failing after 4s Details CI / Type Check (push) Successful in 18s Details CI / Test (push) Successful in 10s Details CI / Release (push) Has been cancelled Details	2025-08-01 11:46:21 +00:00
Kai Chappell	a951413a62	Add instrument interface tests	2025-07-26 20:12:06 +00:00
Kai Chappell	0b58f7e863	Add instrument factory	2025-07-26 19:22:27 +00:00
Kai Chappell	a8bd132269	Implement instrument interfaces in drivers	2025-07-24 18:15:50 +00:00
Kai Chappell	0a8d7e5c69	Add instrument interface protocols	2025-07-19 14:08:46 +00:00
Kai Chappell	ece1803c10	Fix linting: use builtin OSError and TimeoutError instead of socket aliases	2025-07-15 11:15:17 +00:00
Kai Chappell	76d81b21e6	Add driver unit tests	2025-07-10 15:57:02 +00:00
Kai Chappell	4db50421b3	Add PSU and DMM drivers	2025-07-08 09:45:40 +00:00
Kai Chappell	10e1da198e	Add thermal chamber driver	2025-07-04 18:14:37 +00:00
Kai Chappell	8fe97047d1	Add driver base class	2025-06-30 15:04:21 +00:00
Kai Chappell	1f00210b63	Refactor DUTModel from Protocol to ABC for explicit interface implementation	2025-06-29 17:33:28 +00:00
Kai Chappell	95961cd26f	Refactor Transport from Protocol to ABC for explicit interface implementation	2025-06-25 19:25:42 +00:00
Kai Chappell	fe208b0c04	Update specification to mandate ABC over Protocol for maximum type safety	2025-06-24 23:59:34 +00:00
Kai Chappell	d38c40d52d	Add transport layer tests	2025-06-19 15:55:38 +00:00
Kai Chappell	936ed5a279	Implement TCP transport	2025-06-16 13:30:35 +00:00
Kai Chappell	284793df69	Add transport protocol definition	2025-06-14 20:48:34 +00:00
Kai Chappell	e38f514153	Fix linting and type errors for CI - Use X \| None syntax instead of Optional[X] (UP045) - Sort imports in dashboard app (I001) - Remove unnecessary UTF-8 encoding argument (UP012) - Add 'from err' to exception re-raises (B904) - Remove unused imports in integration tests (F401) - Fix useless expression in test (B018) - Cast **1.5 result to float in LDO model (mypy no-any-return) - Use functools.partial instead of lambda in server (mypy misc)	2025-06-12 22:05:46 +00:00
Kai Chappell	cfe8dab7a8	Move InstrumentServer to instruments/transport InstrumentServer is a general-purpose SCPI-over-TCP server that can host any device implementing the SCPIDevice protocol (process method). Moving it from simulation/ to instruments/transport/ reflects this: - simulation package now depends on instruments package - InstrumentServer can host both virtual and real instrument adapters - Added SCPIDevice Protocol for type-safe device registration	2025-06-07 15:15:56 +00:00
Kai Chappell	9e9c0ae0e5	Release v0.1.0-alpha.3 Some checks failed CI / Lint (push) Failing after 4s Details CI / Type Check (push) Failing after 17s Details CI / Test (push) Successful in 9s Details CI / Release (push) Has been cancelled Details	2025-06-02 22:56:53 +00:00
Kai Chappell	a742d57a6f	Add TCP server integration tests Test connection handling, multiple clients, instrument access across all three virtual instruments, physics engine integration, and error handling. Update pytest-asyncio config for v1.x compatibility.	2025-05-30 22:59:33 +00:00
Kai Chappell	2d358062f4	Add simulation server entry point Create SimulationServer that wires physics engine to all virtual instruments and exposes them over TCP. Add 'serve' CLI command to start the server with configurable ports and physics rate.	2025-05-30 19:31:01 +00:00
Kai Chappell	1a489b9106	Implement TCP client handling Add async client connection handling with: - Multiple concurrent connections per port - Line-based SCPI protocol (newline terminated) - start(), stop(), and serve_forever() methods - Proper connection lifecycle and error handling	2025-05-24 13:48:10 +00:00
Kai Chappell	f9e59da32b	Add async TCP server foundation Create InstrumentServer class with asyncio for hosting virtual SCPI instruments over TCP. Supports registering instruments on specific ports with port-to-instrument mapping.	2025-05-22 21:32:38 +00:00
Kai Chappell	a4c01c856d	Add multimeter simulator tests Comprehensive test coverage for MultimeterSim including MEAS:VOLT:DC, MEAS:CURR:DC, CONF, and READ commands. Tests both standalone operation and physics engine integration including temperature-dependent measurements.	2025-05-21 22:55:40 +00:00
Kai Chappell	144e80f87a	Add multimeter simulator Implement SCPI-based virtual DMM with DC voltage and current measurement. Supports MEAS, CONF, and READ commands. Integrates with physics engine for DUT output measurements.	2025-05-16 23:48:11 +00:00
Kai Chappell	e811b21082	Add power supply simulator tests Comprehensive test coverage for PowerSupplySim including VOLT, CURR, OUTP, and MEAS commands. Tests both standalone operation and physics engine integration.	2025-05-12 17:29:00 +00:00
Kai Chappell	9a88a35cc5	Add power supply simulator Implement SCPI-based virtual power supply with voltage/current control and output enable commands. Integrates with physics engine for DUT input voltage simulation.	2025-05-09 20:21:07 +00:00
Kai Chappell	b31324a42a	Add thermal chamber simulator tests Tests for ThermalChamberSim SCPI command responses: - Basic IEEE 488.2 commands (IDN?, RST, *OPC?) - TEMP:SETPOINT set/query - TEMP:ACTUAL? query - TEMP:STAB? stability query - Physics engine integration tests	2025-05-05 21:00:43 +00:00
Kai Chappell	008134844d	Implement thermal chamber SCPI commands - TEMP:SETPOINT: Set/query target temperature - TEMP:ACTUAL?: Query actual chamber temperature from physics engine - TEMP:STAB?: Query temperature stability (within 0.5°C threshold)	2025-05-04 19:34:48 +00:00
Kai Chappell	ae85948539	Add thermal chamber simulator stub Defines ThermalChamberSim class with stub SCPI command handlers for TEMP:SETPOINT, TEMP:ACTUAL?, and TEMP:STAB? commands.	2025-05-02 23:33:16 +00:00
Kai Chappell	bccb8cc420	Add base instrument class Provides SCPI command parsing and dispatch mechanism for virtual instruments. Includes IEEE 488.2 common commands (IDN?, RST, CLS, OPC) and abstract methods for instrument-specific implementations.	2025-04-28 19:24:24 +00:00
Kai Chappell	510e1ba683	Add SCPI parser tests Comprehensive test suite for SCPI command parsing: - SCPICommand dataclass tests (creation, keyword property) - Parser tests for queries, commands, arguments - IEEE 488.2 common command tests (IDN?, RST, etc.) - Edge cases (whitespace, empty strings) - Instrument-specific command tests Also fixed bug where is_query was determined from command string ending rather than header ending (handles queries with arguments).	2025-04-21 13:10:50 +00:00
Kai Chappell	5e69085875	Implement SCPI parser Adds SCPIParser class with parse() method that handles: - IEEE 488.2 common commands (IDN?, RST, etc.) - Query commands (ending with '?') - Commands with comma-separated arguments - Whitespace stripping	2025-04-21 12:03:55 +00:00
Kai Chappell	5053399851	Add SCPI command dataclass Defines SCPICommand dataclass for parsed SCPI commands with: - header: command header (e.g., "TEMP:SETPOINT") - arguments: list of command arguments - is_query: whether command is a query - keyword property: header without trailing '?'	2025-04-16 23:08:32 +00:00
Kai Chappell	d54ada18b2	Remove fragment from sidebar controls (not supported) Sidebar controls cannot be in a fragment. Brief blank on slider change is a Streamlit limitation.	2025-04-15 21:25:23 +00:00
Kai Chappell	252c329562	Put sidebar controls in fragment to prevent page blanking Both controls and display are now fragments, so slider changes don't trigger full page reruns.	2025-04-13 18:47:37 +00:00
Kai Chappell	6e7da7f382	Use st.fragment for smooth dashboard updates Replace st.rerun() with @st.fragment decorator to prevent full page reloads and eliminate UI greying out.	2025-04-08 13:08:15 +00:00
Kai Chappell	75e0a1cc25	Fix dashboard simulation speed with time multiplier - Add time multiplier control (1× to 100× speed) - Calculate steps based on real elapsed time - Add 50ms delay to prevent UI thrashing - Display current speed in Sim Time metric	2025-04-05 17:58:41 +00:00
Kai Chappell	1c0d2ead54	Release v0.1.0-alpha.2 Some checks failed CI / Test (push) Successful in 9s Details CI / Release (push) Has been cancelled Details CI / Lint (push) Failing after 4s Details CI / Type Check (push) Failing after 17s Details	2025-04-03 21:20:13 +00:00
Kai Chappell	2b78a75f51	Add self-heating visualisation	2025-03-29 17:04:13 +00:00
Kai Chappell	15c9033153	Add interactive physics controls	2025-03-24 15:02:51 +00:00
Kai Chappell	0ab1181ec4	Add physics visualisation panel	2025-03-24 14:20:53 +00:00
Kai Chappell	bb3129e69b	Add Streamlit dashboard skeleton	2025-03-18 14:24:17 +00:00
Kai Chappell	14858a087c	Release v0.1.0-alpha.1 Some checks failed CI / Release (push) Has been cancelled Details CI / Lint (push) Failing after 4s Details CI / Type Check (push) Failing after 7s Details CI / Test (push) Successful in 8s Details Physics engine working milestone: - Thermal-electrical coupling simulation - LDO DUT model with temperature dependence - Comprehensive test suite	2025-03-14 19:10:34 +00:00
Kai Chappell	7ecdbe007a	Add physics engine tests Integration tests for thermal-electrical coupling: - Thermal settling (chamber, case, junction) - Self-heating effects with power dissipation - Temperature-dependent electrical behaviour - Complete thermal-electrical feedback loop	2025-03-13 16:42:17 +00:00
Kai Chappell	568d1a6ca4	Implement physics engine stepping Full implementation of step() method with thermal-electrical coupling: - Chamber temperature first-order response to setpoint - Case temperature with self-heating via thermal calculations - Junction temperature from θ_jc thermal resistance - Electrical state from temperature-dependent DUT model - Default LDO model when none provided	2025-03-11 19:23:10 +00:00
Kai Chappell	3db4969e44	Implement LDO DUT model Temperature-dependent LDO voltage regulator model with: - Output voltage tempco (ppm/°C) - Quiescent current tempco - Dropout voltage temperature dependence - Power dissipation calculation (Vin-Vout)Iload + VinIq - Dropout detection Implements DUTModel protocol for physics engine integration.	2025-03-06 21:24:17 +00:00
Kai Chappell	8ef8c18e50	Implement thermal calculation functions Pure functions for first-order thermal response calculations: - Temperature derivative and update using Euler integration - Case temperature with self-heating via θ_ca - Junction temperature calculation via θ_jc - Steady-state junction temperature helper	2025-03-02 20:05:54 +00:00
Kai Chappell	eb13bb5bc4	Add physics model unit tests Test dataclass creation, immutability, equality, and hashability for ThermalState and ElectricalState. Also test PhysicsEngine stub methods.	2025-02-27 21:23:36 +00:00
Kai Chappell	ca4613e318	Rename models.py to state.py to avoid conflict with models/ directory The models.py file conflicts with the models/ subdirectory when importing. Renamed to state.py for clarity.	2025-02-27 19:02:42 +00:00
Kai Chappell	7ca31c9c97	Add physics engine stub Define PhysicsEngine class with stub methods for thermal-electrical simulation. Methods return placeholder values; full implementation will be added in Sprint 3.	2025-02-20 18:59:24 +00:00
Kai Chappell	13d53d13df	Add DUT model protocol Define the DUTModel Protocol interface that all device models must implement to integrate with the physics engine.	2025-02-20 18:53:40 +00:00
Kai Chappell	6a937876a3	Add physics state dataclasses Define frozen dataclasses for ThermalState and ElectricalState to represent immutable simulation state snapshots.	2025-02-15 19:51:02 +00:00
Kai Chappell	85024f8670	Restructure package for domain-driven design Reorganise package structure to improve separation of concerns: - instruments/ - SCPI, transport, drivers, interfaces, factory - simulation/ - physics engine, virtual instruments, server - framework/ - test runner, logger, limits, context - tests/ - thermal/, electrical/ (DVT test implementations) - data/ - repository, models - reporting/ - generator, templates - app/ - CLI, config, dashboard This structure enables: - Reusable instruments package for other test suites - Clear separation of simulation (dev) vs production code - Domain-focused package organisation Updated documentation to reflect new paths.	2025-02-10 12:06:22 +00:00
`@@ -1,3 +1,3 @@`
	`"""py_dvt_ate: Coupled Physics DVT Simulation Platform."""`	`"""py_dvt_ate: Coupled Physics DVT Simulation Platform."""`

	`__version__ = "0.0.1"`	`__version__ = "0.1.0-beta.2"`