Extend AeroAlign with mixed CoG planning and telemetry base

2026-03-11 23:14:33 +01:00
parent 538c3081bf
commit 56890272a0
28 changed files with 1631 additions and 1332 deletions
@@ -1,360 +1,68 @@
 # SkyLogic AeroAlign - Implementation Status

-**Date**: 2026-01-22
-**Phase**: 4 (Differential Measurement) - COMPLETE ✅
-**Progress**: 32/130 tasks (25%)
+**Date**: 2026-03-11  
+**State**: AeroAlign working, CoG integration base prepared

---
+## Repository Status

-## ✅ Completed Work
+The project now has two layers:

-### Phase 1: Setup (7/7 tasks - 100%)
+1. working AeroAlign firmware and UI for IMU-based angle measurement
+2. shared protocol and documentation base for the upcoming CoG scale extension

-**Directory Structure Created**:
-```
-ewd-digiflo/
-├── firmware/
-│   ├── master/src/        ✅ Master firmware source
-│   ├── master/data/       ✅ Web UI location
-│   ├── slave/src/         ✅ Slave firmware source
-├── hardware/
-│   ├── cad/               ✅ 3D models (documentation)
-│   ├── schematics/        ✅ Wiring diagrams + BOM
-│   └── docs/              ✅ Hardware docs
-├── docs/                  ✅ End-user guides
-└── specs/001-wireless-rc-telemetry/  ✅ Design docs
-```
+## Implemented

-**Configuration Files**:
- ✅ `firmware/master/platformio.ini` - ESP32-C3/S3 build config
- ✅ `firmware/slave/platformio.ini` - Multi-slave variants (8 nodes)
- ✅ `firmware/master/src/config.h` - WiFi, GPIO, constants
- ✅ `firmware/slave/src/config.h` - Master MAC, node ID
+### Firmware

---
+- Master firmware builds for `esp32-c3` and `esp32-s3`
+- IMU slave firmware builds for the current slave environments, including S3
+- Master and Slave use the same direct MPU6050 register access approach
+- shared ESP-NOW packet format supports device typing:
+  - `IMU`
+  - `CoG Scale`
+  - `Hybrid`
+- Master data model and UI can already represent CoG-style telemetry fields

-### Phase 2: Foundational (13/13 tasks - 100%)
+### UI

-#### Hardware Foundation
+- current tabs remain angle-focused: `Sensors`, `Differential`, `System`
+- mixed-device node cards are supported
+- differential selection excludes CoG-only nodes
+- Master battery display is hidden when the ADC path is not available

- ✅ **Bill of Materials** (`hardware/schematics/bom.csv`)
-  - Complete component list with Amazon ASINs
-  - Pricing: $72 for 2-sensor system, $289 for 8-sensor system
-  - Alternative components documented
+### Documentation

- ✅ **Wiring Diagram** (`hardware/schematics/sensor_node_wiring.md`)
-  - Complete ESP32-MPU6050-LiPo-TP4056 wiring
-  - Battery monitoring circuit (voltage divider)
-  - Power supply design (HT7333 LDO)
-  - Assembly instructions and troubleshooting
+- README rewritten for combined AeroAlign + CoG direction
+- IMU wiring brought to current C3/S3 and battery-monitoring behavior
+- new CoG wiring guide added
+- BOM converted from placeholder marketplace list to current component overview
+- CAD readme updated to include planned CoG fixtures

- ✅ **3D CAD Documentation** (`hardware/cad/README.md`)
-  - Sensor housing specs (38mm × 28mm × 18mm)
-  - Control surface clips (3mm, 5mm, 8mm)
-  - Print settings for PLA/PETG
-  - Multi-sensor expansion mounts (Phase 8 ready)
+## Current Hardware Documentation

-#### Firmware Foundation - Master Node
+- [README.md](/Users/florianklaner/Github/AeroAlign/README.md)
+- [sensor_node_wiring.md](/Users/florianklaner/Github/AeroAlign/hardware/schematics/sensor_node_wiring.md)
+- [cog_scale_wiring.md](/Users/florianklaner/Github/AeroAlign/hardware/schematics/cog_scale_wiring.md)
+- [bom.csv](/Users/florianklaner/Github/AeroAlign/hardware/schematics/bom.csv)
+- [hardware/cad/README.md](/Users/florianklaner/Github/AeroAlign/hardware/cad/README.md)
+- [AEROALIGN_COG_INTEGRATION.md](/Users/florianklaner/Github/AeroAlign/docs/AEROALIGN_COG_INTEGRATION.md)

- ✅ **IMU Driver** (`firmware/master/src/imu_driver.cpp/h`)
-  - MPU6050 6-axis sensor support
-  - Complementary filter (α=0.98) for angle calculation
-  - ±0.5° accuracy (static measurement)
-  - Temperature monitoring
-  - Calibration support
+## What Works Right Now

- ✅ **Calibration Manager** (`firmware/master/src/calibration.cpp/h`)
-  - NVS (Non-Volatile Storage) persistence
-  - Zero-point offset storage per node
-  - Temperature-tagged calibration
-  - Load/save/clear operations
+- Master AP + web UI
+- IMU node discovery over ESP-NOW
+- calibration and differential measurement for angle nodes
+- S3-safe IMU access path
+- optional battery reporting on Master hardware where ADC is not wired

- ✅ **ESP-NOW Receiver** (`firmware/master/src/espnow_master.cpp/h`)
-  - Receive sensor data from Slaves (10Hz)
-  - Checksum validation (XOR)
-  - Auto-discovery (no manual pairing)
-  - Connection timeout detection (1000ms)
-  - Packet statistics tracking
+## What Is Not Finished Yet

- ✅ **Web Server** (`firmware/master/src/web_server.cpp/h`)
-  - AsyncWebServer (non-blocking)
-  - REST API endpoints:
-    - GET /api/nodes (sensor data)
-    - GET /api/differential (EWD calculation)
-    - POST /api/calibrate (zero sensors)
-    - GET /api/status (system health)
-  - JSON responses (ArduinoJson)
+- dedicated `firmware/cog_slave`
+- HX711 integration
+- tare and scale calibration persistence
+- model profiles for support spacing and target CoG
+- dedicated CoG workflow in the UI

- ✅ **Master Main Loop** (`firmware/master/src/main.cpp`)
-  - WiFi Access Point (SSID: "SkyLogic-AeroAlign")
-  - IP: 192.168.4.1 (captive portal)
-  - IMU sampling (100Hz)
-  - ESP-NOW updates (100ms)
-  - Battery monitoring (1Hz)
-  - Status reporting (10s intervals)
+## Recommended Next Step

-#### Firmware Foundation - Slave Node
-
- ✅ **IMU Driver** (`firmware/slave/src/imu_driver.cpp/h`)
-  - Same as Master (copied)
-
- ✅ **ESP-NOW Transmitter** (`firmware/slave/src/espnow_slave.cpp/h`)
-  - Send sensor data to Master (10Hz)
-  - 15-byte packet format (node_id, pitch, roll, yaw, battery, checksum)
-  - Pairing with Master MAC
-  - Transmission statistics
-
- ✅ **Slave Main Loop** (`firmware/slave/src/main.cpp`)
-  - IMU sampling (100Hz)
-  - ESP-NOW transmission (10Hz / 100ms intervals)
-  - Battery monitoring (1Hz)
-  - Low battery warning (LED flash)
-  - Status reporting (10s intervals)
-
-#### Infrastructure
-
- ✅ **Git Ignore** (`.gitignore`)
-  - PlatformIO build artifacts
-  - IDE files (VSCode, IntelliJ, Eclipse)
-  - Environment files (.env)
-  - OS-specific files (.DS_Store, Thumbs.db)
-
- ✅ **Web UI** (`firmware/master/data/index.html`)
-  - Real-time angle display (10Hz polling)
-  - System status dashboard
-  - Node connection indicators
-  - Battery/RSSI monitoring
-  - Responsive design (mobile-friendly)
-
- ✅ **Documentation** (`README.md`)
-  - Project overview and features
-  - Quick start guide
-  - Hardware requirements
-  - Architecture diagram
-  - API documentation
-  - Development instructions
-
---
-
-### Phase 3: User Story 1 - MVP (12/12 tasks - 100%)
-
-**Web UI Enhancements** (`firmware/master/data/index.html`):
- ✅ Three-tab interface (Sensors, Differential, System)
- ✅ Real-time angle display (10Hz polling)
- ✅ Calibration buttons for each sensor
- ✅ Connection indicators with pulse animation
- ✅ Battery warnings (orange card when <20%)
- ✅ Toast notifications for success/failure
- ✅ Node selectors for differential measurement
- ✅ Color-coded results (green <0.5°, yellow <2.0°, red >2.0°)
- ✅ Responsive mobile design
-
---
-
-### Phase 4: User Story 2 - Differential Measurement (8/8 tasks - 100%)
-
-**Median Filtering Implementation** (`firmware/master/src/web_server.cpp/h`):
- ✅ `DifferentialHistory` data structure
-  - Circular buffer for last 10 readings per node pair
-  - Supports up to 36 unique node pairs
-  - Automatic memory management
-
- ✅ **Median Calculation Algorithm**
-  - Bubble sort for small arrays (10 elements)
-  - Handles even/odd sample counts
-  - Non-destructive (preserves original data)
-
- ✅ **Standard Deviation Calculation**
-  - Sample standard deviation (n-1 denominator)
-  - Measures measurement stability
-  - Color-coded in UI (green <0.1°, yellow <0.3°, red >=0.3°)
-
- ✅ **Enhanced API Response**
-  - `median_diff`: Median of last 10 pitch readings
-  - `median_pitch`: Median pitch differential
-  - `median_roll`: Median roll differential
-  - `std_dev`: Standard deviation of pitch readings
-  - `std_dev_pitch`: Pitch standard deviation
-  - `std_dev_roll`: Roll standard deviation
-  - `readings_count`: Number of samples in buffer (0-10)
-
-**Web UI Enhancements**:
- ✅ Median value display (primary metric)
- ✅ Current reading display (real-time, unfiltered)
- ✅ Standard deviation indicator (measurement quality)
- ✅ Sample count display (buffer fill status)
- ✅ Color-coded stability feedback
-
-**Accuracy Achievement**:
- ✅ ±0.1° accuracy via median filtering (vs ±0.5° raw IMU)
- ✅ Real-time stability monitoring
- ✅ Configurable history depth (10 samples = 1 second at 10Hz)
-
---
-
-## 📊 Implementation Metrics
-
-### Code Statistics
-
-**Lines of Code**:
- Master firmware: ~1,500 lines
- Slave firmware: ~600 lines
- Web UI: ~400 lines
- **Total**: ~2,500 lines
-
-**Files Created**: 25+
- Firmware: 12 files
- Hardware: 3 files
- Documentation: 10+ files
-
-### Test Coverage
-
- ❌ **Unit Tests**: Not yet implemented (planned for Phase 7)
- ❌ **Integration Tests**: Pending hardware validation
- ✅ **API Contract**: Fully documented in contracts/
-
---
-
-## 🔧 What Works Now
-
-### Firmware Features
-
-1. **Master Node**:
-   - WiFi Access Point active
-   - REST API responding to HTTP requests
-   - ESP-NOW receiver listening for Slaves
-   - IMU reading pitch/roll angles
-   - Calibration stored to NVS
-   - Battery monitoring active
-
-2. **Slave Node**:
-   - ESP-NOW transmitter sending data
-   - IMU sampling at 100Hz
-   - Battery percentage calculated
-   - Low battery warnings
-   - Connection status LED
-
-3. **Web Interface**:
-   - Real-time angle display
-   - System status dashboard
-   - Connection indicators
-   - API endpoint links
-
-### Testing Status
-
-**Compilation**: ✅ Both Master and Slave compile successfully
-**Runtime**: ⏳ Awaiting hardware testing
-**API**: ✅ Endpoints respond with proper JSON
-
---
-
-## 🚧 What's Next (Phase 5: User Story 3)
-
-### Immediate Tasks (8 remaining)
-
-1. **Multi-Node Support** (T041-T043):
-   - Support 4-6 simultaneous sensor nodes
-   - Implement scrollable node list in UI
-   - Add node discovery status indicators
-
-2. **Enhanced Node Management** (T044-T046):
-   - Node labeling/naming functionality
-   - Connection quality indicators
-   - Battery status for all nodes
-
-3. **System Scalability** (T047-T048):
-   - Optimize web UI for multiple nodes
-   - Test with 6 physical nodes
-   - Performance validation
-
-### Hardware Validation
-
-**Required Equipment**:
- 2× ESP32-C3 DevKits
- 2× MPU6050 IMU modules
- 2× LiPo batteries (250-400mAh)
- USB-C cables
- Breadboard + jumper wires
-
-**Test Procedure**:
-1. Flash Master firmware
-2. Note Master MAC address from serial output
-3. Update Slave config.h with Master MAC
-4. Flash Slave firmware
-5. Power on both nodes
-6. Connect smartphone to "SkyLogic-AeroAlign" WiFi
-7. Open http://192.168.4.1
-8. Verify real-time angle updates
-
---
-
-## 💡 Key Achievements
-
-### Technical Excellence
-
-1. **Auto-Discovery**: Slaves automatically register with Master (no manual pairing)
-2. **Low Latency**: <20ms ESP-NOW transmission + 100ms web UI refresh = <120ms total
-3. **Robust Protocol**: Checksum validation prevents corrupted data
-4. **Persistent Calibration**: NVS storage survives power cycles
-5. **Multi-Node Ready**: Architecture supports 8 sensors (Phase 8)
-
-### Constitution Compliance
-
-✅ **Cost-Efficiency**: $72 for 2-sensor system (vs. $600 competitors)
-✅ **3D Printing**: All parts <200mm³, <30% support
-✅ **Lightweight**: Target 23g per node (vs. 25g spec)
-✅ **Plug-and-Play**: 3-step setup (power, WiFi, browser)
-
---
-
-## 🐛 Known Issues
-
-1. **Master MAC Hardcoding**: Slave requires manual MAC entry in config.h
-   - **Impact**: Medium (one-time setup)
-   - **Workaround**: Serial monitor shows Master MAC
-   - **Fix**: Phase 8 auto-discovery feature
-
-2. **Web UI Placeholder**: Basic HTML/JS (not full React)
-   - **Impact**: Low (functional but not polished)
-   - **Status**: Phase 3 will add React components
-
-3. **No Physical Testing**: Firmware untested on hardware
-   - **Impact**: High (may have runtime bugs)
-   - **Status**: Awaiting hardware delivery
-
-4. **Missing STL Files**: 3D models documented but not created
-   - **Impact**: Medium (blocks physical assembly)
-   - **Status**: Requires FreeCAD design (Phase 7)
-
---
-
-## 📈 Timeline Estimate
-
-**Completed** (Phases 1-4): ~14 hours
- Phase 1-2 (Setup + Foundation): ~8 hours
- Phase 3 (MVP): ~3 hours
- Phase 4 (Differential): ~3 hours
-
-**Remaining**:
- Phase 5-6 (US3-US4): 6-8 hours
- Phase 7 (Polish): 6-8 hours
- Phase 8 (Multi-Sensor): 10-12 hours
-
-**Total Project**: ~40-50 hours for full feature set
-
---
-
-## 🎯 Next Session Goals
-
-1. **Hardware testing** with 2 physical nodes (validate Phase 3-4 implementation)
-2. **Phase 5**: Multi-node support (4-6 sensors)
-   - Implement scrollable node list in web UI
-   - Add node labeling functionality
-   - Test with multiple Slave nodes
-3. **Phase 6**: Throw gauge mode (control surface deflection)
-4. **3D Printing**: Generate STL files for sensor housing
-5. **Documentation**: Assembly guides and troubleshooting
-
---
-
-**Status**: MVP + Differential Measurement complete! Ready for multi-node expansion. 🚀
+Implement the actual CoG node firmware next, because the protocol, Master-side data path and baseline documentation are now in place.
@@ -1,441 +1,174 @@
-# SkyLogic AeroAlign - Wireless RC Telemetry System
+# SkyLogic AeroAlign

-**Precision Grounded.**
+Wireless RC setup platform for two related jobs:

-A low-cost, open-source wireless digital incidence and throw meter system for RC airplane setup. Replaces traditional spirit levels and pendulum meters with precise IMU-based angle measurement.
+- AeroAlign: digital incidence, reference-angle and differential measurement
+- CoG Scale: center-of-gravity measurement using load cells

---
+Both parts are intended to run in the same ESP32 ecosystem and talk to the same Master over ESP-NOW.

-## 🎯 Project Status
+## Current State

-**Phase 4: Differential Measurement (COMPLETE)** ✅
+Implemented now:

-The MVP is fully functional with advanced differential measurement capabilities:
+- Master firmware with WiFi AP, REST API and existing web UI
+- IMU Master and IMU Slave support with robust MPU6050 access
+- shared telemetry protocol for multiple device types
+- UI support for both IMU nodes and future CoG scale nodes
+- battery monitoring with optional hide/disable behavior on unsupported Master hardware

- ✅ **Master Node Firmware**: WiFi AP, ESP-NOW receiver, IMU driver, web server with REST API
- ✅ **Slave Node Firmware**: ESP-NOW transmitter, IMU driver, battery monitoring
- ✅ **Web UI**: Three-tab interface with real-time sensor display, calibration, and differential measurement
- ✅ **Median Filtering**: ±0.1° accuracy via 10-sample median filter with standard deviation monitoring
- ✅ **Hardware Design**: Bill of Materials ($72 for 2-sensor system), wiring diagrams, 3D printable housing specs
- ✅ **Development Environment**: PlatformIO configurations for ESP32-C3/ESP32-S3
+Prepared but not fully implemented yet:

-**Next Steps**: Phase 5 - Multi-node support for 4-6 simultaneous sensors
+- dedicated HX711-based CoG scale firmware
+- model profiles with support spacing, leading-edge offset and target CoG
+- scale calibration workflow in the web UI

---
-
-## ⚡ Quick Start
-
-### For End Users
-
-1. **Flash Firmware**:
-   ```bash
-   cd firmware/master
-   pio run --target upload
-
-   cd ../slave
-   pio run --target upload
-   ```
-
-2. **Update Slave Configuration**:
-   - Connect Master to USB, open serial monitor (115200 baud)
-   - Note the Master MAC address printed at startup
-   - Edit `firmware/slave/src/config.h` and replace `master_mac` array
-   - Reflash Slave firmware
-
-3. **Power On**:
-   - Power on both Master and Slave nodes
-   - Connect smartphone to WiFi: **"SkyLogic-AeroAlign"**
-   - Open browser: **http://192.168.4.1**
-
-4. **Use**:
-   - Attach sensors to RC model control surfaces
-   - View real-time angles in web UI
-   - Calibrate (zero) sensors via web interface
-
-### For Developers
-
-See [specs/001-wireless-rc-telemetry/quickstart.md](specs/001-wireless-rc-telemetry/quickstart.md) for detailed build instructions.
-
---
-
-## 📋 Features
-
-### Implemented (Phases 1-4: MVP + Differential)
-
-**Core Firmware**:
- ✅ **IMU Driver**: MPU6050 6-axis sensor with complementary filter (±0.5° raw accuracy)
- ✅ **ESP-NOW Protocol**: Low-latency (<20ms) wireless communication between nodes
- ✅ **WiFi Access Point**: Captive portal for smartphone/tablet connection (no internet required)
- ✅ **REST API**: HTTP endpoints for sensor data, calibration, differential, and system status
- ✅ **Calibration**: Zero-point calibration with NVS (Non-Volatile Storage) persistence
- ✅ **Battery Monitoring**: Real-time battery percentage via ADC
- ✅ **Multi-Node Support**: Auto-discovery of up to 8 sensor nodes
-
-**Web UI**:
- ✅ **Real-Time Display**: 10Hz polling with three-tab interface (Sensors, Differential, System)
- ✅ **Calibration Interface**: One-click zero calibration for each sensor
- ✅ **Connection Indicators**: Pulse animation, timeout detection (1000ms)
- ✅ **Battery Warnings**: Visual alerts when <20%
- ✅ **Toast Notifications**: Success/failure feedback
-
-**Differential Measurement**:
- ✅ **Median Filtering**: ±0.1° accuracy via 10-sample circular buffer
- ✅ **Standard Deviation**: Real-time measurement stability indicator
- ✅ **Color-Coded Results**: Green (<0.5°), Yellow (<2.0°), Red (>=2.0°)
- ✅ **EWD Mode**: Wing-to-elevator incidence calculation
- ✅ **Node Pair Selection**: Arbitrary sensor pairs via dropdown
-
-### Planned (Phases 5-8)
-
- 📅 **Multi-Sensor UI**: 4-6 node simultaneous display with scrollable list
- 📅 **Throw Gauge Mode**: Control surface deflection distance measurement
- 📅 **8-Sensor Grid**: Full aircraft setup (wings, ailerons, elevator, rudder)
- 📅 **Sensor Pairing**: Aileron differential, butterfly mode, multi-wing configurations
- 📅 **Specialized Mounts**: Wing surface clips, hinge line mounts, magnetic quick-attach
-
---
-
-## 🔧 Hardware Requirements
-
-### Core Components (Per Sensor Node)
-
-| Component | Spec | Price | Source |
-|-----------|------|-------|--------|
-| ESP32-C3 DevKit | RISC-V 160MHz, WiFi, USB-C | $6.50 | [Amazon](https://amazon.com) |
-| MPU6050 IMU | 6-axis (gyro + accel), I2C | $4.50 | [Amazon](https://amazon.com) |
-| LiPo Battery | 1S 3.7V 250-400mAh | $8.00 | [Amazon](https://amazon.com) |
-| TP4056 Charger | USB-C, overcharge protection | $1.50 | [Amazon](https://amazon.com) |
-| HT7333 LDO | 3.3V 250mA regulator | $0.80 | [Amazon](https://amazon.com) |
-| **Total per node** | | **~$23** | |
-
-**2-Sensor System**: ~$72 (Master + Slave)
-**4-Sensor System**: ~$145
-**8-Sensor System**: ~$289
-
-See [hardware/schematics/bom.csv](hardware/schematics/bom.csv) for complete Bill of Materials.
-
-### 3D Printed Parts
-
- Sensor housing (38mm × 28mm × 18mm)
- Control surface clips (3mm, 5mm, 8mm variants)
- Wing surface mounts (Phase 8)
-
-See [hardware/cad/README.md](hardware/cad/README.md) for STL files and print settings.
-
---
-
-## 📐 Architecture
-
-### System Overview
+## Architecture

 ```
-Master Node (WiFi AP + Web Server + ESP-NOW Receiver)
-    ↑ WiFi (HTTP/JSON)
-    ↑
-Smartphone/Tablet (Web UI)
-
-Master Node
-    ↑ ESP-NOW (2.4GHz)
-    ↑
-Slave Node(s) (0x02-0x09)
+IMU Slave(s) ------\
+                    \
+CoG Scale Node(s) ----> Master ESP32 ----> WiFi AP ----> Browser UI
+                    /
+Master local IMU --/
 ```

-### Master Node Responsibilities
+### Device roles

-1. **WiFi Access Point**: Hosts "SkyLogic-AeroAlign" network (192.168.4.1)
-2. **Web Server**: Serves React UI and REST API endpoints
-3. **ESP-NOW Receiver**: Accepts sensor data from Slave nodes (10Hz)
-4. **IMU Sensor**: Measures Master node's own pitch/roll
-5. **Calibration Manager**: Stores/loads zero-point offsets (NVS)
+- `Master`
+  - hosts `SkyLogic-AeroAlign`
+  - receives ESP-NOW telemetry
+  - serves the web UI and REST API
+  - can also have its own MPU6050
+- `IMU Slave`
+  - remote angle node
+  - sends pitch, roll and yaw fields as angle telemetry
+- `CoG Scale`
+  - future load-cell node
+  - will send front weight, rear weight and computed CoG in the same shared packet

-### Slave Node Responsibilities
+## Telemetry Protocol

-1. **IMU Sensor**: Measures pitch/roll at 100Hz
-2. **ESP-NOW Transmitter**: Sends data to Master at 10Hz
-3. **Battery Monitoring**: Reports battery percentage
-4. **Low Power**: No WiFi AP (only ESP-NOW), extends battery life to 4-5 hours
+The shared packet format is defined in [telemetry_protocol.h](/Users/florianklaner/Github/AeroAlign/firmware/common/telemetry_protocol.h).

-### Data Flow
+Device types currently defined:

-1. Slave IMU samples at 100Hz (10ms intervals)
-2. Slave transmits ESP-NOW packet to Master at 10Hz (100ms intervals)
-3. Master receives packet, validates checksum, updates node data
-4. Web UI polls GET /api/nodes every 100ms (10Hz)
-5. React UI updates angle displays in real-time
+- `DEVICE_TYPE_IMU`
+- `DEVICE_TYPE_COG_SCALE`
+- `DEVICE_TYPE_HYBRID`

---
+For IMU nodes:

-## 🌐 API Endpoints
+- `pitch`, `roll`, `yaw` are angles

-### GET /api/nodes
+For CoG scale nodes:

-Returns all connected sensor nodes with current angles, battery, RSSI.
+- `pitch` => front support weight in grams
+- `roll` => rear support weight in grams
+- `yaw` => CoG position in millimeters

-**Response**:
-```json
-[
-    {
-        "node_id": 1,
-        "label": "Master",
-        "pitch": -2.35,
-        "roll": 0.87,
-        "yaw": 0.0,
-        "battery_percent": 85,
-        "battery_voltage": 3.95,
-        "rssi": -45,
-        "is_connected": true,
-        "last_update_ms": 123456789
-    },
-    {
-        "node_id": 2,
-        "label": "Sensor 1",
-        "pitch": -3.12,
-        "roll": 0.43,
-        ...
-    }
-]
-```
+## Hardware Overview

-### GET /api/differential?node1=1&node2=2
+### IMU nodes

-Calculates differential angle between two nodes (for EWD measurement).
+Use:

-**Response**:
-```json
-{
-    "node1_id": 1,
-    "node2_id": 2,
-    "node1_label": "Wing Root",
-    "node2_label": "Elevator",
-    "angle_diff_pitch": 0.77,
-    "angle_diff_roll": 0.44,
-    "median_diff": 0.75,
-    "std_dev": 0.03,
-    "mode": "EWD"
-}
-```
+- ESP32-C3 or ESP32-S3
+- MPU6050
+- LiPo, charger and 3.3V supply
+- optional battery divider depending on node

-### POST /api/calibrate
+See [sensor_node_wiring.md](/Users/florianklaner/Github/AeroAlign/hardware/schematics/sensor_node_wiring.md).

-Zero-calibrates a sensor node (sets current angle as 0°).
+### CoG scale

-**Request**:
-```json
-{
-    "node_id": 1
-}
-```
+Planned hardware stack:

-**Response**:
-```json
-{
-    "success": true,
-    "message": "Node calibrated",
-    "node_id": 1,
-    "pitch_offset": -2.35,
-    "roll_offset": 0.87,
-    "yaw_offset": 0.0,
-    "timestamp": 1737590400
-}
-```
+- ESP32-C3 or ESP32-S3
+- two HX711 boards
+- two load cells
+- rigid support spacing and repeatable fixtures

-### GET /api/status
+See [cog_scale_wiring.md](/Users/florianklaner/Github/AeroAlign/hardware/schematics/cog_scale_wiring.md).

-System health and statistics.
+### BOM

-**Response**:
-```json
-{
-    "master_battery_percent": 75,
-    "master_battery_voltage": 3.85,
-    "wifi_clients_connected": 1,
-    "wifi_channel": 6,
-    "uptime_seconds": 3600,
-    "esp_now_packets_received": 1200,
-    "esp_now_packet_loss_rate": 0.02,
-    "firmware_version": "1.0.0",
-    "hardware_model": "ESP32-C3",
-    "free_heap_kb": 280
-}
-```
+The BOM is now maintained as a current component overview instead of placeholder shop links:

---
+- [bom.csv](/Users/florianklaner/Github/AeroAlign/hardware/schematics/bom.csv)

-## 🛠️ Development
+## Firmware Layout

-### Project Structure
+### Existing

-```
-ewd-digiflo/
-├── firmware/
-│   ├── master/              # Master node firmware
-│   │   ├── src/
-│   │   │   ├── main.cpp     # WiFi AP + ESP-NOW + Web Server
-│   │   │   ├── imu_driver.cpp/h
-│   │   │   ├── espnow_master.cpp/h
-│   │   │   ├── calibration.cpp/h
-│   │   │   ├── web_server.cpp/h
-│   │   │   └── config.h     # WiFi SSID, GPIO pins, constants
-│   │   ├── data/
-│   │   │   └── index.html   # React web UI (to be implemented)
-│   │   └── platformio.ini
-│   │
-│   └── slave/               # Slave node firmware
-│       ├── src/
-│       │   ├── main.cpp     # ESP-NOW transmitter + IMU
-│       │   ├── imu_driver.cpp/h
-│       │   ├── espnow_slave.cpp/h
-│       │   └── config.h     # Master MAC, node ID
-│       └── platformio.ini
-│
-├── hardware/
-│   ├── cad/                 # 3D printable STL files (placeholders)
-│   ├── schematics/
-│   │   ├── bom.csv          # Bill of Materials
-│   │   └── sensor_node_wiring.md  # Wiring diagrams
-│   └── docs/
-│
-├── docs/                    # End-user documentation
-│   ├── quickstart.md        # Setup guide
-│   ├── calibration.md       # Calibration procedures
-│   └── troubleshooting.md   # Common issues
-│
-└── specs/                   # Design specifications
-    └── 001-wireless-rc-telemetry/
-        ├── spec.md          # Feature specification
-        ├── plan.md          # Implementation plan
-        ├── tasks.md         # Task breakdown (86 tasks)
-        ├── data-model.md    # Data structures
-        ├── research.md      # Component selection
-        ├── quickstart.md    # Developer guide
-        └── contracts/
-            ├── http-api.md  # REST API spec
-            └── espnow-protocol.md  # Binary protocol spec
-```
+- [firmware/master](/Users/florianklaner/Github/AeroAlign/firmware/master)
+- [firmware/slave](/Users/florianklaner/Github/AeroAlign/firmware/slave)
+- [firmware/common](/Users/florianklaner/Github/AeroAlign/firmware/common)

-### Build Instructions
+### Planned

-**Prerequisites**:
- [PlatformIO](https://platformio.org/) (VS Code extension or CLI)
- Python 3.8+ (for esptool.py)
- Git
+- `firmware/cog_slave`
+  - HX711 reading
+  - tare and scale calibration
+  - CoG computation
+  - ESP-NOW transmission as `DEVICE_TYPE_COG_SCALE`
+
+## Build
+
+Master:

-**Build Master Firmware**:
 ```bash
 cd firmware/master
-pio run                    # Compile
-pio run --target upload    # Flash to ESP32
-pio device monitor         # View serial output (115200 baud)
+pio run
 ```

-**Build Slave Firmware**:
+Slave:
+
 ```bash
 cd firmware/slave
-pio run --target upload
-pio device monitor
+pio run -e esp32-s3
+pio run -e slave2-s3
 ```

-**Build All 8 Slave Variants** (Phase 8):
-```bash
-cd firmware/slave
-./build_all_slaves.sh      # Compiles slave1-slave8 with different NODE_IDs
-```
+## Current Configuration Notes

---
+### Slave Master MAC

-## 📊 Project Progress
+The Slave now reads the Master MAC from [config.cpp](/Users/florianklaner/Github/AeroAlign/firmware/slave/src/config.cpp), not `config.h`.

-### Completed (32/130 tasks, 25%)
+### Master battery monitoring

-| Phase | Tasks | Status |
-|-------|-------|--------|
-| **Phase 1: Setup** | 7/7 | ✅ 100% |
-| **Phase 2: Foundational** | 13/13 | ✅ 100% |
-| **Phase 3: User Story 1 (MVP)** | 12/12 | ✅ 100% |
-| **Phase 4: User Story 2** | 8/8 | ✅ 100% |
-| Phase 5: User Story 3 | 0/8 | 📅 Next |
-| Phase 6: User Story 4 | 0/7 | 📅 Not Started |
-| Phase 7: Polish | 0/31 | 📅 Not Started |
-| Phase 8: Multi-Sensor | 0/44 | 📅 Not Started |
+On ESP32-S3 Master boards the battery ADC path is optional. If the divider is not fitted, the firmware and UI hide the battery value instead of showing dummy data.

-### Next Milestones
+## CoG Math

-1. **Phase 5 (Multi-Node)**: Complete User Story 3 - 4-6 Sensor Support
-   - Implement scrollable node list in web UI
-   - Add node labeling/naming functionality
-   - Test with 4-6 physical nodes
+With front and rear supports spaced by `L`:

-2. **Phase 6 (Throw Gauge)**: Control surface throw measurement
-   - Distance measurement mode
-   - Min/max deflection tracking
+`x_cog_from_front_support = rear_weight / (front_weight + rear_weight) * L`

-3. **Phase 7 (Polish)**: Testing and refinement
-   - Unit tests for all modules
-   - 3D printing validation
-   - Comprehensive documentation
+If the front support is offset from the wing leading edge:

---
+`x_cog_from_leading_edge = support_offset_from_leading_edge + x_cog_from_front_support`

-## 🔬 Constitution Compliance
+The current design note is in [AEROALIGN_COG_INTEGRATION.md](/Users/florianklaner/Github/AeroAlign/docs/AEROALIGN_COG_INTEGRATION.md).

-This project adheres to the [EWD-DigiFlow Constitution](.specify/memory/constitution.md):
+## Workflow Plan

-### I. Extreme Cost-Efficiency ✅
- All components available on Amazon
- **$72 per 2-sensor system** (vs. GliderThrow $600 for 8 sensors)
- 77% cost savings compared to competitors
+The planned operating workflow and the recommended hardware roles are documented in:

-### II. 3D Printing Reproducibility ✅
- All parts fit within 200mm × 200mm × 200mm build volume
- Support structures <30% part volume
- Print settings documented for PLA/PETG
+- [WORKFLOW_AND_SYSTEM_PLAN.md](/Users/florianklaner/Github/AeroAlign/docs/WORKFLOW_AND_SYSTEM_PLAN.md)
+- [AIRCRAFT_PROFILE_MODEL.md](/Users/florianklaner/Github/AeroAlign/docs/AIRCRAFT_PROFILE_MODEL.md)

-### III. Lightweight Design ✅
- Each sensor node: ~23g (target: <25g)
- Minimal impact on control surface movement
+## 3D Printed Parts

-### IV. Software Simplicity (Plug-and-Play) ✅
- No app store submission required (web UI)
- No cloud services or internet needed
- 3-step setup: Power on → Connect WiFi → Open browser
+The CAD readme now covers both IMU parts and planned CoG fixtures:

---
+- [hardware/cad/README.md](/Users/florianklaner/Github/AeroAlign/hardware/cad/README.md)

-## 🤝 Contributing
+## Recommended Next Work

-Contributions welcome! This is an open-source project for the RC community.
-
-**Areas Needing Help**:
- Web UI design (React components)
- 3D CAD designs (FreeCAD → STL)
- Hardware testing (different 3D printers, IMU calibration)
- Documentation (assembly guides, troubleshooting)
-
-See [specs/001-wireless-rc-telemetry/tasks.md](specs/001-wireless-rc-telemetry/tasks.md) for detailed task breakdown.
-
---
-
-## 📄 License
-
-**Firmware**: MIT License
-**Hardware Designs** (STL, schematics): Creative Commons BY-SA 4.0
-
---
-
-## 🙏 Acknowledgments
-
- **Adafruit** for MPU6050 and sensor libraries
- **Espressif** for ESP32 Arduino framework and ESP-NOW protocol
- **RC Community** for feature requests and beta testing
-
---
-
-## 📞 Support
-
- **Documentation**: [specs/001-wireless-rc-telemetry/](specs/001-wireless-rc-telemetry/)
- **Issues**: [GitHub Issues](https://github.com/your-org/skylogic-aeroalign/issues)
- **Community**: [RC Groups Forum Thread](https://www.rcgroups.com/forums/showthread.php?12345)
-
---
-
-*SkyLogic AeroAlign - Precision Grounded.*
+1. Add `firmware/cog_slave` with HX711 support.
+2. Add tare and calibration endpoints in the Master API.
+3. Add a dedicated CoG tab in the web UI.
+4. Add aircraft profiles in NVS.
+5. Finalize mechanical design for the two support fixtures.
@@ -0,0 +1,61 @@
+# AeroAlign + CoG Scale Integration
+
+## Zielbild
+
+Das System wird von einem reinen digitalen Einstellwinkelmesser zu einer gemeinsamen RC-Setup-Plattform erweitert:
+
+- AeroAlign-Knoten messen Pitch/Roll fuer EWD, Ruderausschlag und Bezugswinkel.
+- CoG-Scale-Knoten messen Front- und Heckauflagegewicht ueber Load Cells.
+- Ein gemeinsamer ESP32-Master sammelt beide Geraeteklassen ueber ESP-NOW und stellt alles in derselben Web-Oberflaeche bereit.
+
+## Externe Referenz
+
+Die geplante CoG-Funktion orientiert sich konzeptionell an diesem Projekt:
+
+- [RC plane Center of Gravity finder | Hackaday.io](https://hackaday.io/project/202834-rc-plane-center-of-gravity-finder/details)
+
+Aus der Referenz uebernommen:
+
+- zwei digitale Waagen mit ESP32
+- Front- und Heckgewicht als Echtzeitdaten
+- CoG-Berechnung aus dem Abstand der Auflagepunkte
+- Speicherung modellspezifischer Parameter im Geraet
+
+## Mechanisches Modell
+
+Wenn die vordere Auflage bei `x = 0` und die hintere bei `x = L` liegt, dann gilt aus dem Momentengleichgewicht:
+
+`x_cog_from_front_support = rear_weight / (front_weight + rear_weight) * L`
+
+Das ist eine technische Ableitung aus der in der Hackaday-Referenz gezeigten Zwei-Waagen-Anordnung.
+
+Um die Lage relativ zur Fluegelvorderkante zu erhalten:
+
+`x_cog_from_leading_edge = support_offset_from_leading_edge + x_cog_from_front_support`
+
+## Netzwerkmodell
+
+Ein gemeinsames ESP-NOW-Protokoll transportiert nun Geraetetypen:
+
+- `IMU`: klassische AeroAlign-Sensoren
+- `CoG Scale`: Waagenknoten mit Front/Heck/CoG
+- `Hybrid`: spaeter fuer kombinierte Vorrichtungen
+
+Der Master muss deshalb keine getrennten Netze oder Apps mehr betreiben.
+
+## Empfohlene Phase 5
+
+1. Eigenen CoG-Slave auf Basis `firmware/slave` anlegen.
+2. HX711-Treiber und Tare/Kalibrierung integrieren.
+3. Master-API um Modellparameter `support_distance_mm` und `leading_edge_offset_mm` erweitern.
+4. Web-UI um CoG-Ansicht mit Livewerten, Sollwert und Ballast-Rechner erweitern.
+5. NVS-Datenmodell fuer Flugzeugprofile einfuehren.
+
+## Firmware-Schnittstelle
+
+Aktuell ist im Protokoll nur die Transportbasis vorbereitet:
+
+- `pitch/roll/yaw` bleiben fuer IMU-Knoten erhalten.
+- CoG-Scale-Knoten belegen dieselben drei Float-Felder mit `front_weight_g`, `rear_weight_g` und `cog_position_mm`.
+
+Das ist bewusst pragmatisch, damit bestehende ESP-NOW-Kommunikation erhalten bleibt und die eigentliche HX711-Integration als naechster Schritt isoliert umgesetzt werden kann.
@@ -0,0 +1,268 @@
+# Aircraft Profile Model
+
+## Zweck
+
+Diese Datei ist die verbindliche Fachvorgabe fuer das Modul, das AeroAlign und CoG gemeinsam bedienen soll.
+
+Sie legt fest:
+
+- welche Flugzeugprofile es gibt
+- welche Flaechenarten unterschieden werden
+- welche Workflows pro Profil aktiv sind
+- welche Spezialfaelle ausdruecklich anders behandelt werden
+
+## Begriffe
+
+### Feste Flaechen
+
+Feste, nicht verstellte aerodynamische Referenzflaechen.
+
+Beispiele:
+
+- Tragflaeche
+- Dämpfungsflosse Hoehenleitwerk
+- Dämpfungsflosse Seitenleitwerk
+- feste Canard-Flaeche
+
+### Bewegliche Flaechen
+
+Aktiv angelenkte Flaechen oder Klappen.
+
+Beispiele:
+
+- Querruder
+- Hoehenruder
+- Seitenruder
+- Wölbklappe
+- Spoiler
+- Taileron
+- Pendelleitwerk
+
+### Referenzflaeche
+
+Die Flaeche, gegen die eine andere Flaeche gemessen wird.
+
+Regel:
+
+Bewegliche Flaechen werden gegen ihre zugehoerige feste Referenz gemessen, nicht pauschal gegen andere bewegliche Flaechen.
+
+## Grundsaetze
+
+1. `EWD / Referenzgeometrie` ist ein eigener Workflow.
+2. `CG / Schwerpunkt` ist ein eigener Workflow.
+3. `Ruder- und Klappeneinstellung` ist ein eigener Workflow.
+4. `90 Grad Servoarm` ist keine universelle Fachregel und darf nur als optionale Montagehilfe behandelt werden.
+5. `Pendelleitwerk` und `Taileron` sind keine normalen Hoehenruder.
+
+## Profiltypen
+
+### 1. `classic`
+
+Klassisches Flaechenflugzeug mit:
+
+- Tragflaeche
+- Dämpfungsflosse Hoehenleitwerk
+- Hoehenruder
+- Dämpfungsflosse Seitenleitwerk
+- Seitenruder
+- Querruder
+
+Aktive Workflows:
+
+- `reference`
+- `surfaces`
+- `cog`
+- spaeter `throw`
+
+MVP-Status:
+
+- dies ist das primäre Startprofil fuer das System
+
+### 2. `jet_taileron`
+
+Jet mit kombiniertem Hoehen-/Querruder an beweglichen Heckflaechen.
+
+Merkmale:
+
+- keine klassische Trennung zwischen Hoehenruder und Querruder hinten
+- linke und rechte Tailerons muessen symmetrisch und differenziert pruefbar sein
+
+Aktive Workflows:
+
+- `reference`
+- `surfaces`
+- `cog`
+- spaeter `mixing_check`
+
+Sonderregel:
+
+Tailerons werden nicht wie normale Hoehenruder gegen eine Dämpfungsflosse behandelt.
+
+### 3. `stabilator`
+
+All-flying stabilizer oder Pendelhöhenleitwerk.
+
+Merkmale:
+
+- gesamte Flaeche bewegt sich
+- keine feste Dämpfungsflosse als lokale Referenzflaeche
+
+Aktive Workflows:
+
+- `reference`
+- `surfaces`
+- `cog`
+
+Sonderregel:
+
+Die bewegliche Gesamtflaeche wird gegen eine externe Referenz gemessen, typischerweise Tragflaeche oder definierte Vorrichtung.
+
+### 4. `glider_flap`
+
+Segler mit Querrudern, Wölbklappen und oft mehreren Flugphasen.
+
+Merkmale:
+
+- Grundneutralstellung kann je nach Flugphase bewusst nicht null sein
+- Butterfly, Speed, Thermik und Cruise koennen unterschiedliche Sollwerte haben
+
+Aktive Workflows:
+
+- `reference`
+- `surfaces`
+- `cog`
+- spaeter `flight_mode_offsets`
+
+### 5. `delta_elevon`
+
+Delta oder Nurfluegel mit kombinierten Elevons.
+
+Merkmale:
+
+- keine klassische EWD wie beim Leitwerksflugzeug
+- linke und rechte Elevons sind kombinierte Hoehen-/Querruderflaechen
+
+Aktive Workflows:
+
+- `reference`
+- `surfaces`
+- `cog`
+
+Sonderregel:
+
+Es gibt keine klassische Leitwerksreferenz. Das Profil darf keine Leitwerkslogik erzwingen.
+
+## Flaechentypen fuer das Datenmodell
+
+Das Modul soll mindestens folgende Typen unterscheiden:
+
+- `wing_reference`
+- `tailplane_fixed`
+- `fin_fixed`
+- `aileron`
+- `elevator`
+- `rudder`
+- `flap`
+- `spoiler`
+- `taileron`
+- `stabilator`
+- `elevon`
+- `canard_fixed`
+- `canard_control`
+
+## Workflow-Freigabe pro Profil
+
+| Profil | Reference | Surfaces | CoG | Throw später | Speziallogik |
+|--------|-----------|----------|-----|--------------|--------------|
+| `classic` | ja | ja | ja | ja | gering |
+| `jet_taileron` | ja | ja | ja | ja | hoch |
+| `stabilator` | ja | ja | ja | ja | hoch |
+| `glider_flap` | ja | ja | ja | ja | mittel |
+| `delta_elevon` | ja | ja | ja | ja | hoch |
+
+## Messregeln pro Flaechenart
+
+### Querruder
+
+Gegen:
+
+- linke oder rechte Tragflaechenreferenz
+
+### Hoehenruder
+
+Gegen:
+
+- Dämpfungsflosse Hoehenleitwerk
+
+### Seitenruder
+
+Gegen:
+
+- Dämpfungsflosse Seitenleitwerk
+
+### Wölbklappen
+
+Gegen:
+
+- zugehoerige Tragflaechenreferenz
+
+Hinweis:
+
+Die Sollstellung muss nicht `0.0` sein.
+
+### Taileron
+
+Gegen:
+
+- profilabhaengige Heckreferenz oder externe Referenz
+
+### Stabilator
+
+Gegen:
+
+- externe Referenzflaeche
+
+Nicht gegen:
+
+- nicht vorhandene Dämpfungsflosse
+
+## UI-Folgen
+
+Die UI darf nicht einfach fuer alle Modelle dieselben Labels oder Buttons anzeigen.
+
+Pflicht:
+
+- Profilwahl beim Anlegen des Modells
+- sprechende Flaechenrollen
+- nur die fuer das Profil gueltigen Workflows anzeigen
+- Sonderflaechen mit eigenen Begriffen benennen
+
+Beispiele:
+
+- `Elevator` nur bei `classic`
+- `Stabilator` bei `stabilator`
+- `Taileron Left/Right` bei `jet_taileron`
+- `Flap Left/Right` bei `glider_flap`
+
+## MVP-Grenze
+
+Fuer den ersten echten Produktstand soll das Modul fachlich vorbereitet sein, aber operativ auf `classic` optimiert werden.
+
+MVP in der Praxis:
+
+- klassische Tragflaeche
+- Dämpfungsflosse Hoehenleitwerk
+- Hoehenruder
+- Querruder links/rechts
+- Seitenruder optional
+- CoG-Messung
+
+Andere Profile muessen im Datenmodell vorgesehen sein, auch wenn sie anfangs noch nicht vollstaendig in der UI freigeschaltet sind.
+
+## Verbindliche Anweisung fuer die weitere Implementierung
+
+1. Keine harte Verdrahtung auf nur `elevator`, `aileron`, `rudder`.
+2. Workflow-Entscheidungen muessen profilabhaengig sein.
+3. `EWD`, `CG` und `surface setup` bleiben getrennte Modi.
+4. `Dämpfungsflosse` ist der Standardbegriff fuer den feststehenden Leitwerksteil.
+5. `90 Grad Servoarm` darf nie als alleinige Sollbedingung modelliert werden.
@@ -0,0 +1,281 @@
+# AeroAlign + CoG - Workflow and System Plan
+
+## Ziel
+
+Das System soll in der Werkstatt ohne Umdenken bedienbar sein und drei unterschiedliche Aufgaben sauber trennen:
+
+1. feste Referenzflaechen ausrichten
+2. Ruder neutral oder symmetrisch einstellen
+3. Schwerpunkt messen und verschieben
+
+Der wichtigste Grundsatz ist:
+
+Ruder werden nicht primaer gegeneinander verglichen, sondern gegen ihre jeweilige feste Bezugsflaeche.
+
+Zusatz fuer Spezialfaelle:
+
+- EWD, CG und Rudereinstellung bleiben getrennte Ablaeufe
+- Dämpfungsflosse ist der bevorzugte Begriff fuer den feststehenden Leitwerksteil
+- Pendelleitwerk und Taileron werden als eigene Flaechentypen behandelt
+- 90 Grad am Servoarm ist keine universelle aerodynamische Regel
+
+## Bedienlogik
+
+### Was nicht ideal ist
+
+Dieser Ablauf ist fehleranfaellig:
+
+- Modell auf die CoG-Waage stellen
+- Querruder und Hoehenruder direkt miteinander vergleichen
+- eines davon so lange verstellen, bis beide denselben Winkel zeigen
+
+Warum das problematisch ist:
+
+- Tragflaeche und Hoehenleitwerk haben oft unterschiedliche Sollwinkel
+- ein neutrales Hoehenruder ist nicht automatisch derselbe Winkel wie ein neutrales Querruder
+- Sender-Subtrim sollte nicht die mechanische Grundjustage ersetzen
+
+### Besserer Ablauf
+
+1. Modell mechanisch neutralisieren
+2. feste Flaechen und Leitwerke referenzieren
+3. Ruder gegen die zugehoerige feste Flaeche einstellen
+4. Schwerpunkt auf der CoG-Waage einstellen
+5. Neutralstellungen danach kurz erneut pruefen
+
+## Empfohlene Werkstattmodi
+
+### 1. Referenzmodus
+
+Ziel:
+
+- Tragflaeche gegen Hoehenleitwerk
+- Tragflaeche links gegen Tragflaeche rechts
+- EWD oder andere feste Bezugswinkel
+
+Hinweis:
+
+Dieser Modus ist fachlich eigenstaendig und darf nicht mit CoG oder Ruderneutralitaet vermischt werden.
+
+Empfohlene Sensoren:
+
+- ein Sensor auf einer festen Tragflaechen-Referenz
+- ein Sensor auf Hoehenleitwerk oder anderer Referenzflaeche
+
+### 2. Rudermodus
+
+Ziel:
+
+- Querruder links gegen linke Tragflaeche
+- Querruder rechts gegen rechte Tragflaeche
+- Hoehenruder gegen Hoehenleitwerk
+- Seitenruder gegen Seitenleitwerk
+
+Regel:
+
+Jedes bewegliche Ruder wird gegen seine feste Nachbarflaeche verglichen.
+
+Ausnahmen:
+
+- Stabilator gegen externe Referenz
+- Taileron nach Profilregel
+- Wölbklappen mit moeglichem Grundoffset je Flugphase
+
+### 3. CoG-Modus
+
+Ziel:
+
+- Frontgewicht
+- Heckgewicht
+- Schwerpunktlage in mm
+- Abweichung zum Soll-CoG
+
+Hier spielen die IMU-Sensoren nur indirekt mit:
+
+- sie helfen vorher und nachher bei der Neutral- und Referenzpruefung
+- die CoG-Messung selbst basiert auf den Lastzellen
+
+## Minimal sinnvolles Hardware-Set
+
+### Variante A: praxisnahes Basisset
+
+- `1x Master` mit Web UI
+- `2x IMU Slave`
+- `1x CoG Scale` mit zwei Lastzellen
+
+Einsatz:
+
+- Sensor 1 auf fester Tragflaeche oder Referenzlehre
+- Sensor 2 auf Hoehenleitwerk oder Hoehenruder
+- CoG-System separat fuer den Schwerpunkt
+
+Das reicht fuer EWD, Hoehenruder-Neutralitaet und Schwerpunkt.
+
+### Variante B: guter Alltagsausbau
+
+- `1x Master`
+- `4x IMU Slave`
+- `1x CoG Scale`
+
+Einsatz:
+
+- linke Tragflaeche Referenz
+- rechtes Querruder
+- linkes Querruder
+- Hoehenleitwerk oder Hoehenruder
+- CoG-Jig parallel verfuegbar
+
+Damit werden Querruder-Symmetrie und Leitwerksabgleich deutlich komfortabler.
+
+### Variante C: Vollausbau
+
+- `1x Master`
+- `5-6x IMU Slave`
+- `1x CoG Scale`
+
+Zusaetzlich:
+
+- Seitenruder
+- zweite Flaechenreferenz
+- weitere Klappen oder Spoiler
+
+## Empfohlene Hardware-Rollen
+
+### Master
+
+- stationaeres Bediengeraet
+- optional eigener IMU-Sensor fuer Referenzaufgaben
+- WiFi AP und Web UI
+
+### IMU Slaves
+
+- kleine, leichte Clip-Sensoren
+- identische Gehaeuse und Halter, damit Bedienung einheitlich bleibt
+- eindeutige Rollen im UI statt nur Node-IDs
+
+Beispielrollen:
+
+- `Wing Ref Left`
+- `Wing Ref Right`
+- `Aileron Left`
+- `Aileron Right`
+- `Elevator`
+- `Fin / Rudder`
+
+### CoG Scale
+
+- ein eigenes Geraet mit zwei Auflagepunkten
+- zwei Lastzellen
+- fester, reproduzierbarer Auflageabstand
+- idealerweise mit definierter LE-Referenz oder verstellbarem Anschlag
+
+## Bedienbarkeit in der UI
+
+Die UI sollte nicht nur Nodes anzeigen, sondern gefuehrte Aufgaben.
+
+### Empfohlene Hauptansichten
+
+- `Setup`
+  - verbundene Geraete
+  - Akkustand
+  - Rollenbezeichnungen
+- `Reference`
+  - Flaeche gegen Leitwerk
+  - Referenzwinkel
+- `Surfaces`
+  - Querruder, Hoehe, Seite
+  - linke/rechte Symmetrie
+- `CoG`
+  - Frontgewicht
+  - Heckgewicht
+  - aktueller CoG
+  - Soll-CoG
+  - Delta zum Ziel
+
+### Wichtige UX-Regeln
+
+- keine reinen Node-IDs als primaere Anzeige
+- jede Messung braucht eine sprechende Rolle
+- gefuehrte Schritte statt nur Rohdaten
+- CoG-Ansicht und Ruder-Ansicht getrennt halten
+- Kalibrieren klar unterscheiden:
+  - IMU `Zero`
+  - Scale `Tare`
+  - Scale `Weight calibration`
+
+## Datenmodell, das dafuer noetig ist
+
+Pro Modellprofil sollten spaeter gespeichert werden:
+
+- Modellname
+- Flaechenreferenz
+- support distance `L`
+- offset der vorderen Auflage zur Nasenleiste
+- Soll-CoG
+- Rollenbelegung der Sensoren
+- optionale Servotests oder Sollwerte fuer Ruderausschlaege
+
+Die verbindliche Profil- und Flaechentyp-Definition steht in:
+
+- [AIRCRAFT_PROFILE_MODEL.md](/Users/florianklaner/Github/AeroAlign/docs/AIRCRAFT_PROFILE_MODEL.md)
+
+## Mechanische Anforderungen an die CoG-Hardware
+
+Damit das gut zusammenspielt, muss die CoG-Hardware nicht nur elektrisch, sondern auch mechanisch sauber sein.
+
+Pflichtpunkte:
+
+- reproduzierbarer Abstand der beiden Auflagen
+- rutschfeste Kontaktpunkte
+- definierte Flugzeugposition in Längsrichtung
+- steife Basis, damit Lasten nicht durchbiegen
+- einfache Nullstellung ohne Modell
+
+Sinnvoll:
+
+- verstellbare Auflagehoehen
+- verstellbarer LE-Anschlag
+- modulare Auflagen fuer verschiedene Rumpf-/Flaechenformen
+
+## Empfohlener End-to-End-Werkstattablauf
+
+1. Sender auf neutral, Trims und Subtrims auf Ausgangszustand
+2. Servoarme und Gestänge mechanisch sauber einstellen
+3. IMU-Sensor auf Tragflaechen-Referenz setzen
+4. IMU-Sensor auf Hoehenleitwerk oder Hoehenruder setzen
+5. Referenz- und EWD-Werte einstellen
+6. Querruder links und rechts gegen ihre jeweilige Referenz einstellen
+7. Modell auf die CoG-Waage stellen
+8. Akku oder Ballast verschieben, bis Soll-CoG erreicht ist
+9. Danach Ruderneutralitaet und Referenzwerte kurz nachpruefen
+10. Profil speichern
+
+## Konkrete Repo-Folgen
+
+### Naechste Firmware-Schritte
+
+1. `firmware/cog_slave` anlegen
+2. HX711 lesen und mitteln
+3. Tare und Skalierungsfaktoren speichern
+4. Rollen-/Profilverwaltung im Master ergaenzen
+5. neue UI-Ansichten `Reference`, `Surfaces`, `CoG`
+
+### Naechste Hardware-Schritte
+
+1. zwei Lastzellen mechanisch auf definierter Basis montieren
+2. Support-Abstand als feste Konstruktionsgroesse festlegen
+3. LE-Anschlag oder Referenzmarke vorsehen
+4. IMU-Halter fuer feste Bezugsflaechen vereinheitlichen
+
+## Fazit
+
+Ja: dein Gedanke geht in die richtige Richtung.  
+Nein: Hoehenruder und Querruder sollten nicht direkt als gemeinsame Soll-Referenz behandelt werden.
+
+Das bessere System trennt:
+
+- Referenzflaechen
+- Ruderneutralitaet
+- Schwerpunkt
+
+Genau so sollte auch die Hardware und die UI aufgebaut werden.
@@ -0,0 +1,46 @@
+// SkyLogic AeroAlign - Shared telemetry protocol
+//
+// Common ESP-NOW payload format shared by Master and all remote devices.
+
+#ifndef TELEMETRY_PROTOCOL_H
+#define TELEMETRY_PROTOCOL_H
+
+#include <Arduino.h>
+
+enum DeviceType : uint8_t {
+    DEVICE_TYPE_UNKNOWN = 0x00,
+    DEVICE_TYPE_IMU = 0x01,
+    DEVICE_TYPE_COG_SCALE = 0x02,
+    DEVICE_TYPE_HYBRID = 0x03,
+};
+
+inline const char* deviceTypeToString(DeviceType device_type) {
+    switch (device_type) {
+        case DEVICE_TYPE_IMU:
+            return "IMU";
+        case DEVICE_TYPE_COG_SCALE:
+            return "CoG Scale";
+        case DEVICE_TYPE_HYBRID:
+            return "Hybrid";
+        default:
+            return "Unknown";
+    }
+}
+
+// ESP-NOW packet structure shared across all node types.
+// IMU nodes use pitch/roll/yaw normally.
+// CoG Scale nodes map:
+//   pitch -> front support weight (g)
+//   roll  -> rear support weight (g)
+//   yaw   -> computed CoG position (mm)
+struct __attribute__((packed)) ESPNowPacket {
+    uint8_t node_id;
+    uint8_t device_type;
+    float pitch;
+    float roll;
+    float yaw;
+    uint8_t battery;
+    uint8_t checksum;
+};
+
+#endif // TELEMETRY_PROTOCOL_H
@@ -474,7 +474,7 @@
        </div>

        <div class="footer">
-            <p>SkyLogic AeroAlign v1.0.0 | Phase 4: Differential Measurement Complete</p>
+            <p>SkyLogic AeroAlign v1.0.0 | AeroAlign active, CoG integration base in progress</p>
            <p style="margin-top: 10px;">Open source hardware & firmware | <a href="https://github.com" class="api-link">GitHub</a></p>
        </div>
    </div>
@@ -562,6 +562,12 @@
        // Update status display
        function updateStatusDisplay() {
            const statusDiv = document.getElementById('status-bar');
+            const batteryItem = systemStatus.master_battery_available ? `
+                <div class="status-item">
+                    <span class="status-label">Master Battery</span>
+                    <span class="status-value">${systemStatus.master_battery_percent}%</span>
+                </div>
+            ` : '';
            statusDiv.innerHTML = `
                <div class="status-item">
                    <span class="status-label">Uptime</span>
@@ -583,6 +589,7 @@
                    <span class="status-label">Free RAM</span>
                    <span class="status-value">${systemStatus.free_heap_kb} KB</span>
                </div>
+                ${batteryItem}
                <div class="status-item">
                    <span class="status-label">Version</span>
                    <span class="status-value">${systemStatus.firmware_version}</span>
@@ -600,37 +607,57 @@
            }

            nodesDiv.innerHTML = nodes.map(node => {
-                const isWarning = node.battery_percent < 20;
+                const hasBattery = node.battery_available !== false;
+                const isWarning = hasBattery && node.battery_percent < 20;
                const cardClass = !node.is_connected ? 'disconnected' : (isWarning ? 'warning' : '');
                const connClass = node.is_connected ? '' : 'disconnected';
+                const isScaleNode = node.device_type === 2;
+                const batteryMetric = hasBattery ? `
+                            <div class="metric">
+                                <div class="metric-label">Battery</div>
+                                <div class="metric-value">${node.battery_percent}%</div>
+                            </div>
+                        ` : '';
+                const cardTitle = isScaleNode ? (node.label || 'CoG Scale ' + node.node_id) : (node.label || 'Sensor ' + node.node_id);
+                const mainValue = isScaleNode ? `${node.cog_position_mm.toFixed(1)} mm` : `${node.pitch.toFixed(2)}°`;
+                const mainLabel = isScaleNode ? 'CoG Position' : 'Pitch Angle';
+                const metricColumns = hasBattery ? 3 : 2;
+                const metricOneLabel = isScaleNode ? 'Front' : 'Roll';
+                const metricOneValue = isScaleNode ? `${node.front_weight_g.toFixed(0)} g` : `${node.roll.toFixed(2)}°`;
+                const metricTwoLabel = isScaleNode ? 'Rear' : 'Signal';
+                const metricTwoValue = isScaleNode ? `${node.rear_weight_g.toFixed(0)} g` : `${node.rssi} dBm`;
+                const signalMetric = isScaleNode ? '' : `
+                            <div class="metric">
+                                <div class="metric-label">Signal</div>
+                                <div class="metric-value">${node.rssi} dBm</div>
+                            </div>
+                        `;

                return `
                    <div class="node-card ${cardClass}">
                        <div class="connection-indicator ${connClass}"></div>
                        <div class="node-header">
-                            <div class="node-label">${node.label || 'Sensor ' + node.node_id}</div>
+                            <div class="node-label">${cardTitle}</div>
                            <div class="node-id">ID: ${node.node_id}</div>
                        </div>
                        <div class="angle-display">
-                            <div class="angle-value">${node.pitch.toFixed(2)}°</div>
-                            <div class="angle-label">Pitch Angle</div>
+                            <div class="angle-value">${mainValue}</div>
+                            <div class="angle-label">${mainLabel}</div>
                        </div>
-                        <div class="node-metrics">
+                        <div class="node-metrics" style="grid-template-columns: repeat(${isScaleNode ? metricColumns : metricColumns}, 1fr);">
                            <div class="metric">
-                                <div class="metric-label">Roll</div>
-                                <div class="metric-value">${node.roll.toFixed(2)}°</div>
+                                <div class="metric-label">${metricOneLabel}</div>
+                                <div class="metric-value">${metricOneValue}</div>
                            </div>
+                            ${batteryMetric}
                            <div class="metric">
-                                <div class="metric-label">Battery</div>
-                                <div class="metric-value">${node.battery_percent}%</div>
-                            </div>
-                            <div class="metric">
-                                <div class="metric-label">Signal</div>
-                                <div class="metric-value">${node.rssi} dBm</div>
+                                <div class="metric-label">${metricTwoLabel}</div>
+                                <div class="metric-value">${metricTwoValue}</div>
                            </div>
+                            ${signalMetric}
                        </div>
                        <button class="calibrate-btn" onclick="calibrateNode(${node.node_id})" ${!node.is_connected ? 'disabled' : ''}>
-                            ${!node.is_connected ? 'Disconnected' : '⚙ Calibrate (Zero)'}
+                            ${!node.is_connected ? 'Disconnected' : (isScaleNode ? '⚙ Tare / Calibrate' : '⚙ Calibrate (Zero)')}
                        </button>
                    </div>
                `;
@@ -642,7 +669,7 @@
            const select1 = document.getElementById('node1-select');
            const select2 = document.getElementById('node2-select');

-            const options = nodes.filter(n => n.is_connected).map(n =>
+            const options = nodes.filter(n => n.is_connected && n.device_type !== 2).map(n =>
                `<option value="${n.node_id}">${n.label || 'Node ' + n.node_id} (${n.node_id})</option>`
            ).join('');

@@ -2,7 +2,7 @@
 ;
 ; Master node hosts:
 ; - WiFi Access Point (SSID: SkyLogic-AeroAlign)
-; - AsyncWebServer with React web UI
+; - AsyncWebServer with browser-based web UI
 ; - ESP-NOW receiver for Slave node data
 ; - MPU6050/BNO055 IMU driver
 ;
@@ -55,7 +55,7 @@ monitor_filters = esp32_exception_decoder

 ; Build flags
 build_flags =
-    -D ARDUINO_USB_CDC_ON_BOOT=1
+    -D ARDUINO_USB_CDC_ON_BOOT=0
    -D CORE_DEBUG_LEVEL=3
    -D CONFIG_ASYNC_TCP_RUNNING_CORE=0
    -D CONFIG_ASYNC_TCP_USE_WDT=0
@@ -33,22 +33,36 @@
 #define WIFI_AP_SUBNET IPAddress(255, 255, 255, 0)

 // ========================================
-// GPIO Pin Definitions (ESP32-C3)
+// GPIO Pin Definitions
 // ========================================

-// I2C pins for IMU (MPU6050/BNO055)
+#if defined(CONFIG_IDF_TARGET_ESP32S3)
+
+// ESP32-S3 defaults
+#define IMU_I2C_SDA 4   // GPIO4 (SDA)
+#define IMU_I2C_SCL 5   // GPIO5 (SCL)
+#define IMU_I2C_FREQ 100000  // 100kHz for better signal margin on jumper wires
+#define BATTERY_ADC_PIN 1   // GPIO1 (ADC1), avoids GPIO0 boot strap
+#define BATTERY_MONITOR_ENABLED 0  // Set to 1 only if a divider is actually wired
+#define STATUS_LED_PIN -1   // Board-dependent on S3 modules, disabled by default
+#define HARDWARE_MODEL "ESP32-S3"
+
+#else
+
 #define IMU_I2C_SDA 4   // GPIO4 (SDA)
 #define IMU_I2C_SCL 5   // GPIO5 (SCL)
 #define IMU_I2C_FREQ 400000  // 400kHz (fast mode)
+#define BATTERY_ADC_PIN 0   // GPIO0 (ADC1_CH0)
+#define BATTERY_MONITOR_ENABLED 1
+#define STATUS_LED_PIN 10   // GPIO10 (built-in LED on some boards)
+#define HARDWARE_MODEL "ESP32-C3"
+
+#endif

 // Battery monitoring (ADC)
-// Voltage divider: LiPo+ -> 10kΩ -> GPIO0 -> 10kΩ -> GND
-#define BATTERY_ADC_PIN 0   // GPIO0 (ADC1_CH0)
+// Voltage divider: LiPo+ -> 10kΩ -> BATTERY_ADC_PIN -> 10kΩ -> GND
 #define BATTERY_VOLTAGE_DIVIDER 2.0  // 10kΩ + 10kΩ = 2:1 ratio

-// Status LED (optional)
-#define STATUS_LED_PIN 10   // GPIO10 (built-in LED on some boards)
-
 // Power control (optional, for deep sleep)
 #define POWER_ENABLE_PIN -1  // Not used (always on)

@@ -67,8 +81,8 @@
 // If no packet received from Slave for this duration, mark as disconnected
 #define ESPNOW_TIMEOUT_MS 1000

-// Expected packet size (15 bytes: node_id + pitch + roll + yaw + battery + checksum)
-#define ESPNOW_PACKET_SIZE 15
+// Expected packet size (16 bytes: node_id + device_type + pitch + roll + yaw + battery + checksum)
+#define ESPNOW_PACKET_SIZE 16

 // ========================================
 // IMU Configuration
@@ -132,9 +146,6 @@
 // Firmware version
 #define FIRMWARE_VERSION "1.0.0"

-// Hardware model
-#define HARDWARE_MODEL "ESP32-C3"
-
 // System name
 #define SYSTEM_NAME "SkyLogic AeroAlign"

@@ -161,9 +161,18 @@ void ESPNowMaster::handleReceivedPacket(const uint8_t *mac, const uint8_t *data,

    if (node) {
        // Update node data
+        node->device_type = static_cast<DeviceType>(packet.device_type);
        node->pitch = packet.pitch;
        node->roll = packet.roll;
        node->yaw = packet.yaw;
+        node->front_weight_g = 0.0f;
+        node->rear_weight_g = 0.0f;
+        node->cog_position_mm = 0.0f;
+        if (node->device_type == DEVICE_TYPE_COG_SCALE || node->device_type == DEVICE_TYPE_HYBRID) {
+            node->front_weight_g = packet.pitch;
+            node->rear_weight_g = packet.roll;
+            node->cog_position_mm = packet.yaw;
+        }
        node->battery_percent = packet.battery;
        node->is_connected = true;
        node->last_update_ms = millis();
@@ -176,8 +185,9 @@ void ESPNowMaster::handleReceivedPacket(const uint8_t *mac, const uint8_t *data,
        total_packets_received++;

        #ifdef DEBUG_ESPNOW_PACKETS
-        Serial.printf("[ESP-NOW] RX from 0x%02X: pitch=%.2f° roll=%.2f° battery=%d%% RSSI=%ddBm\n",
-                     packet.node_id, packet.pitch, packet.roll, packet.battery, node->rssi);
+        Serial.printf("[ESP-NOW] RX from 0x%02X (%s): a=%.2f b=%.2f c=%.2f battery=%d%% RSSI=%ddBm\n",
+                     packet.node_id, deviceTypeToString(node->device_type),
+                     packet.pitch, packet.roll, packet.yaw, packet.battery, node->rssi);
        #endif
    }
 }
@@ -206,11 +216,15 @@ void ESPNowMaster::registerNode(uint8_t node_id, const uint8_t *mac) {
        if (nodes[i].node_id == 0) {
            // Initialize new node
            nodes[i].node_id = node_id;
+            nodes[i].device_type = DEVICE_TYPE_UNKNOWN;
            memcpy(nodes[i].mac_address, mac, 6);
            snprintf(nodes[i].label, sizeof(nodes[i].label), "Sensor %d", node_id - 1);
            nodes[i].pitch = 0.0;
            nodes[i].roll = 0.0;
            nodes[i].yaw = 0.0;
+            nodes[i].front_weight_g = 0.0;
+            nodes[i].rear_weight_g = 0.0;
+            nodes[i].cog_position_mm = 0.0;
            nodes[i].pitch_offset = 0.0;
            nodes[i].roll_offset = 0.0;
            nodes[i].yaw_offset = 0.0;
@@ -12,26 +12,20 @@
 #include <Arduino.h>
 #include <esp_now.h>
 #include <WiFi.h>
-
-// ESP-NOW packet structure (must match Slave's packet format)
-// Total: 15 bytes
-struct __attribute__((packed)) ESPNowPacket {
-    uint8_t node_id;        // Sender node ID (0x02-0x09)
-    float pitch;            // Pitch angle (degrees)
-    float roll;             // Roll angle (degrees)
-    float yaw;              // Yaw angle (degrees, unused)
-    uint8_t battery;        // Battery percentage (0-100)
-    uint8_t checksum;       // XOR checksum of bytes 0-13
-};
+#include "../../common/telemetry_protocol.h"

 // Sensor node data structure
 struct SensorNode {
    uint8_t node_id;
+    DeviceType device_type;
    uint8_t mac_address[6];
    char label[32];
    float pitch;
    float roll;
    float yaw;
+    float front_weight_g;
+    float rear_weight_g;
+    float cog_position_mm;
    float pitch_offset;
    float roll_offset;
    float yaw_offset;
@@ -7,10 +7,24 @@
 #include "config.h"
 #include <math.h>

+namespace {
+constexpr uint8_t MPU6050_REG_SMPLRT_DIV = 0x19;
+constexpr uint8_t MPU6050_REG_CONFIG = 0x1A;
+constexpr uint8_t MPU6050_REG_GYRO_CONFIG = 0x1B;
+constexpr uint8_t MPU6050_REG_ACCEL_CONFIG = 0x1C;
+constexpr uint8_t MPU6050_REG_PWR_MGMT_1 = 0x6B;
+constexpr uint8_t MPU6050_REG_WHO_AM_I = 0x75;
+constexpr uint8_t MPU6050_REG_ACCEL_XOUT_H = 0x3B;
+constexpr uint8_t MPU6050_DEVICE_ID = 0x68;
+constexpr float MPU6050_ACCEL_LSB_PER_G = 16384.0f;
+constexpr float MPU6050_GYRO_LSB_PER_DEG_S = 131.0f;
+constexpr float GRAVITY_M_S2 = 9.80665f;
+}
+
 IMU_Driver::IMU_Driver()
    : pitch_offset(0.0), roll_offset(0.0), yaw_offset(0.0),
      filtered_pitch(0.0), filtered_roll(0.0), last_update_us(0),
-      alpha(COMPLEMENTARY_FILTER_ALPHA), connected(false) {
+      alpha(COMPLEMENTARY_FILTER_ALPHA), connected(false), wire(&Wire) {
    // Initialize data structure
    memset(&data, 0, sizeof(IMU_Data));
 }
@@ -21,11 +35,27 @@ bool IMU_Driver::begin(uint8_t sda_pin, uint8_t scl_pin, uint32_t i2c_freq) {
    #endif

    // Initialize I2C
-    Wire.begin(sda_pin, scl_pin, i2c_freq);
+    wire = &Wire;
+    wire->begin(sda_pin, scl_pin, i2c_freq);
+    wire->setTimeOut(50);
+    delay(20);

-    // Try to initialize MPU6050
-    if (!mpu.begin(IMU_I2C_ADDRESS, &Wire)) {
-        last_error = "MPU6050 not found at 0x68. Check wiring!";
+    // Probe device first so wiring / bus-speed failures are visible in logs.
+    wire->beginTransmission(IMU_I2C_ADDRESS);
+    uint8_t i2c_error = wire->endTransmission();
+    if (i2c_error != 0) {
+        last_error = "I2C probe failed for MPU6050 at 0x68";
+        #ifdef DEBUG_SERIAL_ENABLED
+        Serial.printf("[IMU] ERROR: %s (Wire err=%u, SDA=%u, SCL=%u, %luHz)\n",
+                     last_error.c_str(), i2c_error, sda_pin, scl_pin, (unsigned long)i2c_freq);
+        #endif
+        connected = false;
+        return false;
+    }
+
+    uint8_t who_am_i = 0;
+    if (!readRegister(MPU6050_REG_WHO_AM_I, who_am_i)) {
+        last_error = "MPU6050 WHO_AM_I read failed";
        #ifdef DEBUG_SERIAL_ENABLED
        Serial.printf("[IMU] ERROR: %s\n", last_error.c_str());
        #endif
@@ -33,19 +63,33 @@ bool IMU_Driver::begin(uint8_t sda_pin, uint8_t scl_pin, uint32_t i2c_freq) {
        return false;
    }

+    #ifdef DEBUG_SERIAL_ENABLED
+    Serial.printf("[IMU] WHO_AM_I = 0x%02X\n", who_am_i);
+    #endif
+
+    if (who_am_i != MPU6050_DEVICE_ID) {
+        #ifdef DEBUG_SERIAL_ENABLED
+        Serial.println("[IMU] WARNING: Unexpected WHO_AM_I, continuing with MPU6050-compatible init");
+        #endif
+    }
+
    #ifdef DEBUG_SERIAL_ENABLED
    Serial.printf("[IMU] MPU6050 initialized at 0x%02X\n", IMU_I2C_ADDRESS);
    #endif

-    // Configure MPU6050 settings
-    // Accelerometer range: ±2g (sufficient for static measurement)
-    mpu.setAccelerometerRange(MPU6050_RANGE_2_G);
-
-    // Gyroscope range: ±250 deg/s (low range for better resolution)
-    mpu.setGyroRange(MPU6050_RANGE_250_DEG);
-
-    // Filter bandwidth: 21Hz (balance noise reduction and responsiveness)
-    mpu.setFilterBandwidth(MPU6050_BAND_21_HZ);
+    // Wake sensor and configure ranges / filtering.
+    if (!writeRegister(MPU6050_REG_PWR_MGMT_1, 0x01) ||
+        !writeRegister(MPU6050_REG_SMPLRT_DIV, 0x07) ||
+        !writeRegister(MPU6050_REG_CONFIG, 0x04) ||
+        !writeRegister(MPU6050_REG_GYRO_CONFIG, 0x00) ||
+        !writeRegister(MPU6050_REG_ACCEL_CONFIG, 0x00)) {
+        last_error = "MPU6050 register configuration failed";
+        #ifdef DEBUG_SERIAL_ENABLED
+        Serial.printf("[IMU] ERROR: %s\n", last_error.c_str());
+        #endif
+        connected = false;
+        return false;
+    }

    // Wait for IMU to stabilize
    delay(100);
@@ -60,11 +104,16 @@ bool IMU_Driver::begin(uint8_t sda_pin, uint8_t scl_pin, uint32_t i2c_freq) {
    int valid_samples = 0;

    for (int i = 0; i < IMU_CALIBRATION_SAMPLES; i++) {
-        sensors_event_t accel, gyro, temp;
-        if (mpu.getEvent(&accel, &gyro, &temp)) {
+        uint8_t buffer[14];
+        if (readRegisters(MPU6050_REG_ACCEL_XOUT_H, buffer, sizeof(buffer))) {
+            int16_t raw_ax = (buffer[0] << 8) | buffer[1];
+            int16_t raw_ay = (buffer[2] << 8) | buffer[3];
+            int16_t raw_az = (buffer[4] << 8) | buffer[5];
+            float ax = (raw_ax / MPU6050_ACCEL_LSB_PER_G) * GRAVITY_M_S2;
+            float ay = (raw_ay / MPU6050_ACCEL_LSB_PER_G) * GRAVITY_M_S2;
+            float az = (raw_az / MPU6050_ACCEL_LSB_PER_G) * GRAVITY_M_S2;
            float pitch_raw, roll_raw;
-            calculateAccelAngles(accel.acceleration.x, accel.acceleration.y, accel.acceleration.z,
-                               pitch_raw, roll_raw);
+            calculateAccelAngles(ax, ay, az, pitch_raw, roll_raw);
            pitch_sum += pitch_raw;
            roll_sum += roll_raw;
            valid_samples++;
@@ -72,14 +121,21 @@ bool IMU_Driver::begin(uint8_t sda_pin, uint8_t scl_pin, uint32_t i2c_freq) {
        delay(10);  // 100Hz sampling
    }

-    if (valid_samples > 0) {
+    if (valid_samples == 0) {
+        last_error = "MPU6050 data read failed during calibration";
+        #ifdef DEBUG_SERIAL_ENABLED
+        Serial.printf("[IMU] ERROR: %s\n", last_error.c_str());
+        #endif
+        connected = false;
+        return false;
+    }
+
    pitch_offset = pitch_sum / valid_samples;
    roll_offset = roll_sum / valid_samples;
    #ifdef DEBUG_SERIAL_ENABLED
    Serial.printf("[IMU] Calibration complete. Offsets: pitch=%.2f°, roll=%.2f°\n",
                 pitch_offset, roll_offset);
    #endif
-    }

    connected = true;
    last_update_us = micros();
@@ -91,15 +147,29 @@ bool IMU_Driver::update() {
        return false;
    }

-    // Get sensor events
-    sensors_event_t accel, gyro, temp;
-    if (!mpu.getEvent(&accel, &gyro, &temp)) {
+    uint8_t buffer[14];
+    if (!readRegisters(MPU6050_REG_ACCEL_XOUT_H, buffer, sizeof(buffer))) {
        #ifdef DEBUG_SERIAL_ENABLED
        Serial.println("[IMU] ERROR: Failed to read sensor data");
        #endif
        return false;
    }

+    int16_t raw_ax = (buffer[0] << 8) | buffer[1];
+    int16_t raw_ay = (buffer[2] << 8) | buffer[3];
+    int16_t raw_az = (buffer[4] << 8) | buffer[5];
+    int16_t raw_temp = (buffer[6] << 8) | buffer[7];
+    int16_t raw_gx = (buffer[8] << 8) | buffer[9];
+    int16_t raw_gy = (buffer[10] << 8) | buffer[11];
+    int16_t raw_gz = (buffer[12] << 8) | buffer[13];
+
+    float ax = (raw_ax / MPU6050_ACCEL_LSB_PER_G) * GRAVITY_M_S2;
+    float ay = (raw_ay / MPU6050_ACCEL_LSB_PER_G) * GRAVITY_M_S2;
+    float az = (raw_az / MPU6050_ACCEL_LSB_PER_G) * GRAVITY_M_S2;
+    float gx_deg_s = raw_gx / MPU6050_GYRO_LSB_PER_DEG_S;
+    float gy_deg_s = raw_gy / MPU6050_GYRO_LSB_PER_DEG_S;
+    float gz_deg_s = raw_gz / MPU6050_GYRO_LSB_PER_DEG_S;
+
    // Calculate time delta (dt) in seconds
    uint32_t now_us = micros();
    float dt = (now_us - last_update_us) / 1000000.0;  // Convert to seconds
@@ -111,22 +181,21 @@ bool IMU_Driver::update() {
    }

    // Store raw sensor data
-    data.accel_x = accel.acceleration.x;
-    data.accel_y = accel.acceleration.y;
-    data.accel_z = accel.acceleration.z;
-    data.gyro_x = gyro.gyro.x;
-    data.gyro_y = gyro.gyro.y;
-    data.gyro_z = gyro.gyro.z;
-    data.temperature = temp.temperature;
+    data.accel_x = ax;
+    data.accel_y = ay;
+    data.accel_z = az;
+    data.gyro_x = gx_deg_s * M_PI / 180.0;
+    data.gyro_y = gy_deg_s * M_PI / 180.0;
+    data.gyro_z = gz_deg_s * M_PI / 180.0;
+    data.temperature = (raw_temp / 340.0f) + 36.53f;
    data.timestamp = millis();

    // Calculate pitch and roll from accelerometer (gravity vector)
    float accel_pitch, accel_roll;
-    calculateAccelAngles(accel.acceleration.x, accel.acceleration.y, accel.acceleration.z,
-                        accel_pitch, accel_roll);
+    calculateAccelAngles(ax, ay, az, accel_pitch, accel_roll);

    // Apply complementary filter (fuse gyro + accel)
-    applyComplementaryFilter(accel_pitch, accel_roll, gyro.gyro.x, gyro.gyro.y, dt);
+    applyComplementaryFilter(accel_pitch, accel_roll, data.gyro_x, data.gyro_y, dt);

    // Apply calibration offsets
    data.pitch = constrainAngle(filtered_pitch - pitch_offset);
@@ -253,3 +322,35 @@ float IMU_Driver::constrainAngle(float angle) {
    while (angle < -180.0) angle += 360.0;
    return angle;
 }
+
+bool IMU_Driver::writeRegister(uint8_t reg, uint8_t value) {
+    wire->beginTransmission(IMU_I2C_ADDRESS);
+    wire->write(reg);
+    wire->write(value);
+    return wire->endTransmission() == 0;
+}
+
+bool IMU_Driver::readRegister(uint8_t reg, uint8_t &value) {
+    if (!readRegisters(reg, &value, 1)) {
+        return false;
+    }
+    return true;
+}
+
+bool IMU_Driver::readRegisters(uint8_t reg, uint8_t *buffer, size_t len) {
+    wire->beginTransmission(IMU_I2C_ADDRESS);
+    wire->write(reg);
+    if (wire->endTransmission(false) != 0) {
+        return false;
+    }
+
+    size_t received = wire->requestFrom((uint8_t)IMU_I2C_ADDRESS, (uint8_t)len, (uint8_t)true);
+    if (received != len) {
+        return false;
+    }
+
+    for (size_t i = 0; i < len; i++) {
+        buffer[i] = wire->read();
+    }
+    return true;
+}
@@ -8,8 +8,6 @@

 #include <Arduino.h>
 #include <Wire.h>
-#include <Adafruit_MPU6050.h>
-#include <Adafruit_Sensor.h>

 // IMU data structure
 struct IMU_Data {
@@ -60,8 +58,8 @@ public:
    String getLastError() const;

 private:
-    // Adafruit MPU6050 driver instance
-    Adafruit_MPU6050 mpu;
+    // Active I2C bus for the IMU
+    TwoWire *wire;

    // Current IMU data
    IMU_Data data;
@@ -93,6 +91,11 @@ private:

    // Constrain angle to -180 to +180 range
    float constrainAngle(float angle);
+
+    // Low-level MPU6050 register access
+    bool writeRegister(uint8_t reg, uint8_t value);
+    bool readRegister(uint8_t reg, uint8_t &value);
+    bool readRegisters(uint8_t reg, uint8_t *buffer, size_t len);
 };

 #endif // IMU_DRIVER_H
@@ -23,6 +23,8 @@ IMU_Driver imu;
 ESPNowMaster espnow;
 CalibrationManager calibration;
 WebServerManager* webserver = nullptr;
+uint8_t master_battery_percent = 0;
+float master_battery_voltage = 0.0f;

 // ========================================
 // WiFi AP Setup
@@ -75,7 +77,12 @@ bool setupWiFiAP() {
 // Battery Monitoring (Master)
 // ========================================

-uint8_t readBatteryPercent() {
+bool readBatteryState(float &battery_voltage, uint8_t &battery_percent) {
+    #if !BATTERY_MONITOR_ENABLED || BATTERY_ADC_PIN < 0
+    battery_voltage = 0.0f;
+    battery_percent = 0;
+    return false;
+    #else
    // Read battery voltage via ADC
    int adc_value = analogRead(BATTERY_ADC_PIN);

@@ -83,7 +90,7 @@ uint8_t readBatteryPercent() {
    float voltage_at_adc = (adc_value / 4095.0) * 3.3;

    // Multiply by voltage divider ratio (2:1)
-    float battery_voltage = voltage_at_adc * BATTERY_VOLTAGE_DIVIDER;
+    battery_voltage = voltage_at_adc * BATTERY_VOLTAGE_DIVIDER;

    // Convert to percentage (LiPo: 3.0V = 0%, 4.2V = 100%)
    float percent = ((battery_voltage - BATTERY_VOLTAGE_MIN) /
@@ -93,7 +100,9 @@ uint8_t readBatteryPercent() {
    if (percent < 0.0) percent = 0.0;
    if (percent > 100.0) percent = 100.0;

-    return (uint8_t)percent;
+    battery_percent = (uint8_t)percent;
+    return true;
+    #endif
 }

 // ========================================
@@ -119,8 +128,10 @@ void setup() {
    digitalWrite(STATUS_LED_PIN, LOW);
    #endif

-    // Initialize battery ADC
+    // Initialize battery ADC only if a voltage divider is present.
+    #if BATTERY_MONITOR_ENABLED && BATTERY_ADC_PIN >= 0
    pinMode(BATTERY_ADC_PIN, INPUT);
+    #endif

    // ========================================
    // Step 1: Setup WiFi AP
@@ -237,7 +248,7 @@ void setup() {
    Serial.println("[Setup] Initializing Web Server...");
    #endif

-    webserver = new WebServerManager(&espnow, &calibration, &imu);
+    webserver = new WebServerManager(&espnow, &calibration, &imu, &master_battery_percent, &master_battery_voltage);

    if (!webserver->begin()) {
        #ifdef DEBUG_SERIAL_ENABLED
@@ -277,8 +288,6 @@ void loop() {
    static uint32_t last_espnow_update_ms = 0;
    static uint32_t last_battery_read_ms = 0;
    static uint32_t last_stats_print_ms = 0;
-    static uint8_t battery_percent = 100;
-
    uint32_t now = millis();

    // ========================================
@@ -312,13 +321,10 @@ void loop() {
    if (now - last_battery_read_ms >= 1000) {  // 1000ms = 1Hz
        last_battery_read_ms = now;

-        // Read battery percentage
-        battery_percent = readBatteryPercent();
-
-        // Check for low battery
-        if (battery_percent <= BATTERY_WARNING_PERCENT) {
+        if (readBatteryState(master_battery_voltage, master_battery_percent) &&
+            master_battery_percent <= BATTERY_WARNING_PERCENT) {
            #ifdef DEBUG_SERIAL_ENABLED
-            Serial.printf("[Battery] WARNING: Low battery (%d%%)\n", battery_percent);
+            Serial.printf("[Battery] WARNING: Low battery (%d%%)\n", master_battery_percent);
            #endif

            // Flash LED to warn user
@@ -358,7 +364,11 @@ void loop() {
        Serial.println("Master Node Status Report");
        Serial.println("========================================");
        Serial.printf("Uptime: %lu seconds\n", now / 1000);
-        Serial.printf("Battery: %d%%\n", battery_percent);
+        #if BATTERY_MONITOR_ENABLED
+        Serial.printf("Battery: %d%% (%.2fV)\n", master_battery_percent, master_battery_voltage);
+        #else
+        Serial.println("Battery: not connected");
+        #endif
        Serial.println("----------------------------------------");
        Serial.printf("WiFi: %d clients connected\n", wifi_clients);
        Serial.printf("WiFi: http://%s\n", WIFI_AP_IP.toString().c_str());
@@ -5,10 +5,14 @@
 #include "web_server.h"
 #include "config.h"
 #include <ArduinoJson.h>
+#include <SPIFFS.h>
 #include <math.h>

-WebServerManager::WebServerManager(ESPNowMaster* espnow, CalibrationManager* calibration, IMU_Driver* imu)
-    : espnow(espnow), calibration(calibration), master_imu(imu), server(nullptr), pair_count(0) {
+WebServerManager::WebServerManager(ESPNowMaster* espnow, CalibrationManager* calibration, IMU_Driver* imu,
+                                   const uint8_t* master_battery_percent, const float* master_battery_voltage)
+    : espnow(espnow), calibration(calibration), master_imu(imu), server(nullptr),
+      master_battery_percent(master_battery_percent), master_battery_voltage(master_battery_voltage),
+      pair_count(0) {
 }

 bool WebServerManager::begin() {
@@ -16,6 +20,14 @@ bool WebServerManager::begin() {
    Serial.println("[WebServer] Initializing HTTP server...");
    #endif

+    if (!SPIFFS.begin(true)) {
+        last_error = "SPIFFS mount failed";
+        #ifdef DEBUG_SERIAL_ENABLED
+        Serial.printf("[WebServer] ERROR: %s\n", last_error.c_str());
+        #endif
+        return false;
+    }
+
    // Create server instance
    server = new AsyncWebServer(HTTP_SERVER_PORT);

@@ -45,11 +57,13 @@ bool WebServerManager::begin() {
        this->handleGetStatus(request);
    });

-    // GET / - Serve web UI (placeholder for now)
+    // GET / - Serve web UI
    server->on("/", HTTP_GET, [this](AsyncWebServerRequest *request) {
        this->handleRoot(request);
    });

+    server->serveStatic("/", SPIFFS, "/").setDefaultFile("index.html");
+
    // 404 handler
    server->onNotFound([this](AsyncWebServerRequest *request) {
        this->handleNotFound(request);
@@ -93,15 +107,19 @@ void WebServerManager::handleGetNodes(AsyncWebServerRequest *request) {
        JsonObject master_node = nodes_array.createNestedObject();
        master_node["node_id"] = 1;
        master_node["label"] = "Master";
+        master_node["device_type"] = DEVICE_TYPE_IMU;
+        master_node["device_type_label"] = deviceTypeToString(DEVICE_TYPE_IMU);

        float pitch, roll, yaw;
        master_imu->getAngles(pitch, roll, yaw);
        master_node["pitch"] = pitch;
        master_node["roll"] = roll;
        master_node["yaw"] = yaw;
-
-        master_node["battery_percent"] = 85;  // TODO: Implement Master battery monitoring
-        master_node["battery_voltage"] = 3.9;
+        master_node["battery_available"] = BATTERY_MONITOR_ENABLED;
+        if (BATTERY_MONITOR_ENABLED && master_battery_percent && master_battery_voltage) {
+            master_node["battery_percent"] = *master_battery_percent;
+            master_node["battery_voltage"] = *master_battery_voltage;
+        }
        master_node["rssi"] = 0;
        master_node["is_connected"] = true;
        master_node["last_update_ms"] = millis();
@@ -116,9 +134,15 @@ void WebServerManager::handleGetNodes(AsyncWebServerRequest *request) {
            JsonObject node_obj = nodes_array.createNestedObject();
            node_obj["node_id"] = nodes[i].node_id;
            node_obj["label"] = nodes[i].label;
+            node_obj["device_type"] = nodes[i].device_type;
+            node_obj["device_type_label"] = deviceTypeToString(nodes[i].device_type);
            node_obj["pitch"] = nodes[i].pitch;
            node_obj["roll"] = nodes[i].roll;
            node_obj["yaw"] = nodes[i].yaw;
+            node_obj["front_weight_g"] = nodes[i].front_weight_g;
+            node_obj["rear_weight_g"] = nodes[i].rear_weight_g;
+            node_obj["cog_position_mm"] = nodes[i].cog_position_mm;
+            node_obj["battery_available"] = true;
            node_obj["battery_percent"] = nodes[i].battery_percent;
            node_obj["battery_voltage"] = nodes[i].battery_voltage;
            node_obj["rssi"] = nodes[i].rssi;
@@ -158,7 +182,7 @@ void WebServerManager::handleGetDifferential(AsyncWebServerRequest *request) {
        // (we'll handle this below)
    } else {
        node1 = espnow->getNode(node1_id);
-        if (!node1 || !node1->is_connected) {
+        if (!node1 || !node1->is_connected || node1->device_type == DEVICE_TYPE_COG_SCALE) {
            request->send(404, "application/json", "{\"error\":\"Node 1 not found or disconnected\"}");
            return;
        }
@@ -169,7 +193,7 @@ void WebServerManager::handleGetDifferential(AsyncWebServerRequest *request) {
        // Use Master IMU directly
    } else {
        node2 = espnow->getNode(node2_id);
-        if (!node2 || !node2->is_connected) {
+        if (!node2 || !node2->is_connected || node2->device_type == DEVICE_TYPE_COG_SCALE) {
            request->send(404, "application/json", "{\"error\":\"Node 2 not found or disconnected\"}");
            return;
        }
@@ -323,8 +347,11 @@ void WebServerManager::handleGetStatus(AsyncWebServerRequest *request) {

    // Build JSON response
    DynamicJsonDocument doc(1024);
-    doc["master_battery_percent"] = 75;  // TODO: Implement Master battery monitoring
-    doc["master_battery_voltage"] = 3.85;
+    doc["master_battery_available"] = BATTERY_MONITOR_ENABLED;
+    if (BATTERY_MONITOR_ENABLED && master_battery_percent && master_battery_voltage) {
+        doc["master_battery_percent"] = *master_battery_percent;
+        doc["master_battery_voltage"] = *master_battery_voltage;
+    }
    doc["wifi_clients_connected"] = WiFi.softAPgetStationNum();
    doc["wifi_channel"] = WIFI_CHANNEL;
    doc["uptime_seconds"] = millis() / 1000;
@@ -344,31 +371,7 @@ void WebServerManager::handleRoot(AsyncWebServerRequest *request) {
    #ifdef DEBUG_HTTP_REQUESTS
    Serial.println("[WebServer] GET /");
    #endif
-
-    // Serve web UI (placeholder - will be replaced with actual index.html)
-    String html = R"(
-<!DOCTYPE html>
-<html>
-<head>
-    <title>SkyLogic AeroAlign</title>
-    <meta charset="utf-8">
-    <meta name="viewport" content="width=device-width, initial-scale=1">
-</head>
-<body>
-    <h1>SkyLogic AeroAlign</h1>
-    <p>Web UI placeholder - Full React interface will be implemented in next task</p>
-    <p>API Endpoints:</p>
-    <ul>
-        <li><a href="/api/nodes">/api/nodes</a></li>
-        <li><a href="/api/status">/api/status</a></li>
-        <li>/api/differential?node1=1&node2=2</li>
-        <li>POST /api/calibrate</li>
-    </ul>
-</body>
-</html>
-)";
-
-    request->send(200, "text/html", html);
+    request->send(SPIFFS, "/index.html", "text/html");
 }

 void WebServerManager::handleNotFound(AsyncWebServerRequest *request) {
@@ -20,7 +20,8 @@
 class WebServerManager {
 public:
    // Constructor
-    WebServerManager(ESPNowMaster* espnow, CalibrationManager* calibration, IMU_Driver* imu);
+    WebServerManager(ESPNowMaster* espnow, CalibrationManager* calibration, IMU_Driver* imu,
+                     const uint8_t* master_battery_percent, const float* master_battery_voltage);

    // Initialize web server
    bool begin();
@@ -36,6 +37,8 @@ private:
    ESPNowMaster* espnow;
    CalibrationManager* calibration;
    IMU_Driver* master_imu;
+    const uint8_t* master_battery_percent;
+    const float* master_battery_voltage;

    // Last error message
    String last_error;
@@ -27,8 +27,6 @@ build_flags =
 ; Library dependencies
 lib_deps =
    Wire                                      ; I2C for IMU
-    adafruit/Adafruit MPU6050@^2.2.4         ; MPU6050 IMU driver
-    adafruit/Adafruit BNO055@^1.6.0          ; BNO055 IMU driver (optional)

 ; Partition scheme (minimal, no web server)
 board_build.partitions = min_spiffs.csv
@@ -59,8 +57,6 @@ build_flags =
 ; Library dependencies (same as C3)
 lib_deps =
    Wire
-    adafruit/Adafruit MPU6050@^2.2.4
-    adafruit/Adafruit BNO055@^1.6.0

 ; Partition scheme
 board_build.partitions = min_spiffs.csv
@@ -77,47 +73,69 @@ upload_speed = 921600
 [env:slave1]
 extends = env:esp32-c3
 build_flags =
-    ${env:esp32-c3.build_flags}
+    -D ARDUINO_USB_CDC_ON_BOOT=1
+    -D CORE_DEBUG_LEVEL=3
    -D NODE_ID=0x02

 [env:slave2]
 extends = env:esp32-c3
 build_flags =
-    ${env:esp32-c3.build_flags}
+    -D ARDUINO_USB_CDC_ON_BOOT=1
+    -D CORE_DEBUG_LEVEL=3
    -D NODE_ID=0x03

 [env:slave3]
 extends = env:esp32-c3
 build_flags =
-    ${env:esp32-c3.build_flags}
+    -D ARDUINO_USB_CDC_ON_BOOT=1
+    -D CORE_DEBUG_LEVEL=3
    -D NODE_ID=0x04

 [env:slave4]
 extends = env:esp32-c3
 build_flags =
-    ${env:esp32-c3.build_flags}
+    -D ARDUINO_USB_CDC_ON_BOOT=1
+    -D CORE_DEBUG_LEVEL=3
    -D NODE_ID=0x05

 [env:slave5]
 extends = env:esp32-c3
 build_flags =
-    ${env:esp32-c3.build_flags}
+    -D ARDUINO_USB_CDC_ON_BOOT=1
+    -D CORE_DEBUG_LEVEL=3
    -D NODE_ID=0x06

 [env:slave6]
 extends = env:esp32-c3
 build_flags =
-    ${env:esp32-c3.build_flags}
+    -D ARDUINO_USB_CDC_ON_BOOT=1
+    -D CORE_DEBUG_LEVEL=3
    -D NODE_ID=0x07

 [env:slave7]
 extends = env:esp32-c3
 build_flags =
-    ${env:esp32-c3.build_flags}
+    -D ARDUINO_USB_CDC_ON_BOOT=1
+    -D CORE_DEBUG_LEVEL=3
    -D NODE_ID=0x08

 [env:slave8]
 extends = env:esp32-c3
 build_flags =
-    ${env:esp32-c3.build_flags}
+    -D ARDUINO_USB_CDC_ON_BOOT=1
+    -D CORE_DEBUG_LEVEL=3
    -D NODE_ID=0x09
+
+[env:slave1-s3]
+extends = env:esp32-s3
+build_flags =
+    -D ARDUINO_USB_CDC_ON_BOOT=1
+    -D CORE_DEBUG_LEVEL=3
+    -D NODE_ID=0x02
+
+[env:slave2-s3]
+extends = env:esp32-s3
+build_flags =
+    -D ARDUINO_USB_CDC_ON_BOOT=1
+    -D CORE_DEBUG_LEVEL=3
+    -D NODE_ID=0x03
@@ -0,0 +1,3 @@
+#include <stdint.h>
+
+uint8_t master_mac[6] = {0x24, 0x58, 0x7C, 0xDE, 0x81, 0x90};
@@ -17,15 +17,13 @@
 // ========================================

 // Master node MAC address
-// **IMPORTANT**: Replace this with your Master's actual MAC address
+// **IMPORTANT**: Set this to your Master's actual MAC address in config.cpp
 // To find Master MAC:
 //   1. Flash Master firmware
 //   2. Connect Master to USB, open serial monitor (115200 baud)
 //   3. Master prints MAC at boot: "Master MAC: 24:6F:28:12:34:56"
-//   4. Copy MAC into this array, reflash Slave
-//
-// Format: {0xAA, 0xBB, 0xCC, 0xDD, 0xEE, 0xFF}
-uint8_t master_mac[6] = {0x00, 0x00, 0x00, 0x00, 0x00, 0x00};  // REPLACE WITH ACTUAL MAC
+//   4. Copy MAC into firmware/slave/src/config.cpp, then reflash Slave
+extern uint8_t master_mac[6];

 // Slave node ID (unique identifier for this Slave)
 // Default: 0x02 (first Slave)
@@ -43,26 +41,40 @@ uint8_t master_mac[6] = {0x00, 0x00, 0x00, 0x00, 0x00, 0x00};  // REPLACE WITH A
 // 100ms = 10Hz update rate (balances latency and power consumption)
 #define ESPNOW_SEND_INTERVAL_MS 100

-// ESP-NOW packet size (15 bytes: node_id + pitch + roll + yaw + battery + checksum)
-#define ESPNOW_PACKET_SIZE 15
+// ESP-NOW packet size (16 bytes: node_id + device_type + pitch + roll + yaw + battery + checksum)
+#define ESPNOW_PACKET_SIZE 16

 // ========================================
-// GPIO Pin Definitions (ESP32-C3)
+// GPIO Pin Definitions
 // ========================================

-// I2C pins for IMU (MPU6050/BNO055)
+#if defined(CONFIG_IDF_TARGET_ESP32S3)
+
+// ESP32-S3 defaults
+#define IMU_I2C_SDA 4   // GPIO4 (SDA)
+#define IMU_I2C_SCL 5   // GPIO5 (SCL)
+#define IMU_I2C_FREQ 100000  // 100kHz for better signal margin on jumper wires
+#define BATTERY_ADC_PIN 1   // GPIO1 (ADC1), avoids GPIO0 boot strap
+#define BATTERY_MONITOR_ENABLED 1
+#define STATUS_LED_PIN -1   // Board-dependent on S3 modules, disabled by default
+#define HARDWARE_MODEL "ESP32-S3"
+
+#else
+
 #define IMU_I2C_SDA 4   // GPIO4 (SDA)
 #define IMU_I2C_SCL 5   // GPIO5 (SCL)
 #define IMU_I2C_FREQ 400000  // 400kHz (fast mode)
+#define BATTERY_ADC_PIN 0   // GPIO0 (ADC1_CH0)
+#define BATTERY_MONITOR_ENABLED 1
+#define STATUS_LED_PIN 10   // GPIO10 (built-in LED on some boards)
+#define HARDWARE_MODEL "ESP32-C3"
+
+#endif

 // Battery monitoring (ADC)
-// Voltage divider: LiPo+ -> 10kΩ -> GPIO0 -> 10kΩ -> GND
-#define BATTERY_ADC_PIN 0   // GPIO0 (ADC1_CH0)
+// Voltage divider: LiPo+ -> 10kΩ -> BATTERY_ADC_PIN -> 10kΩ -> GND
 #define BATTERY_VOLTAGE_DIVIDER 2.0  // 10kΩ + 10kΩ = 2:1 ratio

-// Status LED (optional)
-#define STATUS_LED_PIN 10   // GPIO10 (built-in LED on some boards)
-
 // Power control (optional, for deep sleep)
 #define POWER_ENABLE_PIN -1  // Not used (always on)

@@ -101,9 +113,6 @@ uint8_t master_mac[6] = {0x00, 0x00, 0x00, 0x00, 0x00, 0x00};  // REPLACE WITH A
 // Firmware version
 #define FIRMWARE_VERSION "1.0.0"

-// Hardware model
-#define HARDWARE_MODEL "ESP32-C3"
-
 // System name
 #define SYSTEM_NAME "SkyLogic AeroAlign Slave"

@@ -77,31 +77,45 @@ bool ESPNowSlave::begin() {
 }

 bool ESPNowSlave::sendData(float pitch, float roll, float yaw, uint8_t battery) {
+    ESPNowPacket packet;
+    packet.node_id = node_id;
+    packet.device_type = DEVICE_TYPE_IMU;
+    packet.pitch = pitch;
+    packet.roll = roll;
+    packet.yaw = yaw;
+    packet.battery = battery;
+    packet.checksum = calculateChecksum((uint8_t*)&packet, sizeof(packet) - 1);
+    return sendPacket(packet);
+}
+
+bool ESPNowSlave::sendScaleData(float front_weight_g, float rear_weight_g, float cog_position_mm, uint8_t battery) {
+    ESPNowPacket packet;
+    packet.node_id = node_id;
+    packet.device_type = DEVICE_TYPE_COG_SCALE;
+    packet.pitch = front_weight_g;
+    packet.roll = rear_weight_g;
+    packet.yaw = cog_position_mm;
+    packet.battery = battery;
+    packet.checksum = calculateChecksum((uint8_t*)&packet, sizeof(packet) - 1);
+    return sendPacket(packet);
+}
+
+bool ESPNowSlave::sendPacket(const ESPNowPacket &packet) {
    if (!paired) {
        last_error = "Not paired with Master";
        return false;
    }

-    // Build packet
-    ESPNowPacket packet;
-    packet.node_id = node_id;
-    packet.pitch = pitch;
-    packet.roll = roll;
-    packet.yaw = yaw;
-    packet.battery = battery;
-
-    // Calculate checksum (XOR of bytes 0-13)
-    packet.checksum = calculateChecksum((uint8_t*)&packet, sizeof(packet) - 1);
-
    // Send packet
-    esp_err_t result = esp_now_send(master_mac, (uint8_t*)&packet, sizeof(packet));
+    esp_err_t result = esp_now_send(master_mac, (const uint8_t*)&packet, sizeof(packet));

    if (result == ESP_OK) {
        total_packets_sent++;

        #ifdef DEBUG_ESPNOW_PACKETS
-        Serial.printf("[ESP-NOW] TX: pitch=%.2f° roll=%.2f° battery=%d%% checksum=0x%02X\n",
-                     pitch, roll, battery, packet.checksum);
+        Serial.printf("[ESP-NOW] TX (%s): a=%.2f b=%.2f c=%.2f battery=%d%% checksum=0x%02X\n",
+                     deviceTypeToString(static_cast<DeviceType>(packet.device_type)),
+                     packet.pitch, packet.roll, packet.yaw, packet.battery, packet.checksum);
        #endif

        return true;
@@ -11,17 +11,7 @@
 #include <Arduino.h>
 #include <esp_now.h>
 #include <WiFi.h>
-
-// ESP-NOW packet structure (must match Master's packet format)
-// Total: 15 bytes
-struct __attribute__((packed)) ESPNowPacket {
-    uint8_t node_id;        // Sender node ID (0x02-0x09)
-    float pitch;            // Pitch angle (degrees)
-    float roll;             // Roll angle (degrees)
-    float yaw;              // Yaw angle (degrees, unused)
-    uint8_t battery;        // Battery percentage (0-100)
-    uint8_t checksum;       // XOR checksum of bytes 0-13
-};
+#include "../../common/telemetry_protocol.h"

 // ESP-NOW Slave Manager class
 class ESPNowSlave {
@@ -35,6 +25,9 @@ public:
    // Send sensor data packet to Master
    bool sendData(float pitch, float roll, float yaw, uint8_t battery);

+    // Send CoG scale packet to Master
+    bool sendScaleData(float front_weight_g, float rear_weight_g, float cog_position_mm, uint8_t battery);
+
    // Get transmission statistics
    void getStatistics(uint32_t &total_sent, uint32_t &total_failed, float &success_rate);

@@ -70,6 +63,8 @@ private:

    // Calculate XOR checksum
    uint8_t calculateChecksum(const uint8_t *data, int len);
+
+    bool sendPacket(const ESPNowPacket &packet);
 };

 #endif // ESPNOW_SLAVE_H
@@ -7,10 +7,24 @@
 #include "config.h"
 #include <math.h>

+namespace {
+constexpr uint8_t MPU6050_REG_SMPLRT_DIV = 0x19;
+constexpr uint8_t MPU6050_REG_CONFIG = 0x1A;
+constexpr uint8_t MPU6050_REG_GYRO_CONFIG = 0x1B;
+constexpr uint8_t MPU6050_REG_ACCEL_CONFIG = 0x1C;
+constexpr uint8_t MPU6050_REG_PWR_MGMT_1 = 0x6B;
+constexpr uint8_t MPU6050_REG_WHO_AM_I = 0x75;
+constexpr uint8_t MPU6050_REG_ACCEL_XOUT_H = 0x3B;
+constexpr uint8_t MPU6050_DEVICE_ID = 0x68;
+constexpr float MPU6050_ACCEL_LSB_PER_G = 16384.0f;
+constexpr float MPU6050_GYRO_LSB_PER_DEG_S = 131.0f;
+constexpr float GRAVITY_M_S2 = 9.80665f;
+}
+
 IMU_Driver::IMU_Driver()
    : pitch_offset(0.0), roll_offset(0.0), yaw_offset(0.0),
      filtered_pitch(0.0), filtered_roll(0.0), last_update_us(0),
-      alpha(COMPLEMENTARY_FILTER_ALPHA), connected(false) {
+      alpha(COMPLEMENTARY_FILTER_ALPHA), connected(false), wire(&Wire) {
    // Initialize data structure
    memset(&data, 0, sizeof(IMU_Data));
 }
@@ -21,31 +35,46 @@ bool IMU_Driver::begin(uint8_t sda_pin, uint8_t scl_pin, uint32_t i2c_freq) {
    #endif

    // Initialize I2C
-    Wire.begin(sda_pin, scl_pin, i2c_freq);
+    wire = &Wire;
+    wire->begin(sda_pin, scl_pin, i2c_freq);
+    wire->setTimeOut(50);
+    delay(20);

-    // Try to initialize MPU6050
-    if (!mpu.begin(IMU_I2C_ADDRESS, &Wire)) {
-        last_error = "MPU6050 not found at 0x68. Check wiring!";
+    wire->beginTransmission(IMU_I2C_ADDRESS);
+    uint8_t i2c_error = wire->endTransmission();
+    if (i2c_error != 0) {
+        last_error = "I2C probe failed for MPU6050 at 0x68";
        #ifdef DEBUG_SERIAL_ENABLED
-        Serial.printf("[IMU] ERROR: %s\n", last_error.c_str());
+        Serial.printf("[IMU] ERROR: %s (Wire err=%u, SDA=%u, SCL=%u, %luHz)\n",
+                     last_error.c_str(), i2c_error, sda_pin, scl_pin, (unsigned long)i2c_freq);
        #endif
        connected = false;
        return false;
    }

    #ifdef DEBUG_SERIAL_ENABLED
-    Serial.printf("[IMU] MPU6050 initialized at 0x%02X\n", IMU_I2C_ADDRESS);
+    uint8_t who_am_i = 0;
+    if (!readRegister(MPU6050_REG_WHO_AM_I, who_am_i)) {
+        last_error = "MPU6050 WHO_AM_I read failed";
+        Serial.printf("[IMU] ERROR: %s\n", last_error.c_str());
+        connected = false;
+        return false;
+    }
+    Serial.printf("[IMU] WHO_AM_I = 0x%02X\n", who_am_i);
    #endif

-    // Configure MPU6050 settings
-    // Accelerometer range: ±2g (sufficient for static measurement)
-    mpu.setAccelerometerRange(MPU6050_RANGE_2_G);
-
-    // Gyroscope range: ±250 deg/s (low range for better resolution)
-    mpu.setGyroRange(MPU6050_RANGE_250_DEG);
-
-    // Filter bandwidth: 21Hz (balance noise reduction and responsiveness)
-    mpu.setFilterBandwidth(MPU6050_BAND_21_HZ);
+    if (!writeRegister(MPU6050_REG_PWR_MGMT_1, 0x01) ||
+        !writeRegister(MPU6050_REG_SMPLRT_DIV, 0x07) ||
+        !writeRegister(MPU6050_REG_CONFIG, 0x04) ||
+        !writeRegister(MPU6050_REG_GYRO_CONFIG, 0x00) ||
+        !writeRegister(MPU6050_REG_ACCEL_CONFIG, 0x00)) {
+        last_error = "MPU6050 register configuration failed";
+        #ifdef DEBUG_SERIAL_ENABLED
+        Serial.printf("[IMU] ERROR: %s\n", last_error.c_str());
+        #endif
+        connected = false;
+        return false;
+    }

    // Wait for IMU to stabilize
    delay(100);
@@ -60,11 +89,16 @@ bool IMU_Driver::begin(uint8_t sda_pin, uint8_t scl_pin, uint32_t i2c_freq) {
    int valid_samples = 0;

    for (int i = 0; i < IMU_CALIBRATION_SAMPLES; i++) {
-        sensors_event_t accel, gyro, temp;
-        if (mpu.getEvent(&accel, &gyro, &temp)) {
+        uint8_t buffer[14];
+        if (readRegisters(MPU6050_REG_ACCEL_XOUT_H, buffer, sizeof(buffer))) {
+            int16_t raw_ax = (buffer[0] << 8) | buffer[1];
+            int16_t raw_ay = (buffer[2] << 8) | buffer[3];
+            int16_t raw_az = (buffer[4] << 8) | buffer[5];
+            float ax = (raw_ax / MPU6050_ACCEL_LSB_PER_G) * GRAVITY_M_S2;
+            float ay = (raw_ay / MPU6050_ACCEL_LSB_PER_G) * GRAVITY_M_S2;
+            float az = (raw_az / MPU6050_ACCEL_LSB_PER_G) * GRAVITY_M_S2;
            float pitch_raw, roll_raw;
-            calculateAccelAngles(accel.acceleration.x, accel.acceleration.y, accel.acceleration.z,
-                               pitch_raw, roll_raw);
+            calculateAccelAngles(ax, ay, az, pitch_raw, roll_raw);
            pitch_sum += pitch_raw;
            roll_sum += roll_raw;
            valid_samples++;
@@ -72,14 +106,21 @@ bool IMU_Driver::begin(uint8_t sda_pin, uint8_t scl_pin, uint32_t i2c_freq) {
        delay(10);  // 100Hz sampling
    }

-    if (valid_samples > 0) {
+    if (valid_samples == 0) {
+        last_error = "MPU6050 data read failed during calibration";
+        #ifdef DEBUG_SERIAL_ENABLED
+        Serial.printf("[IMU] ERROR: %s\n", last_error.c_str());
+        #endif
+        connected = false;
+        return false;
+    }
+
    pitch_offset = pitch_sum / valid_samples;
    roll_offset = roll_sum / valid_samples;
    #ifdef DEBUG_SERIAL_ENABLED
    Serial.printf("[IMU] Calibration complete. Offsets: pitch=%.2f°, roll=%.2f°\n",
                 pitch_offset, roll_offset);
    #endif
-    }

    connected = true;
    last_update_us = micros();
@@ -91,15 +132,29 @@ bool IMU_Driver::update() {
        return false;
    }

-    // Get sensor events
-    sensors_event_t accel, gyro, temp;
-    if (!mpu.getEvent(&accel, &gyro, &temp)) {
+    uint8_t buffer[14];
+    if (!readRegisters(MPU6050_REG_ACCEL_XOUT_H, buffer, sizeof(buffer))) {
        #ifdef DEBUG_SERIAL_ENABLED
        Serial.println("[IMU] ERROR: Failed to read sensor data");
        #endif
        return false;
    }

+    int16_t raw_ax = (buffer[0] << 8) | buffer[1];
+    int16_t raw_ay = (buffer[2] << 8) | buffer[3];
+    int16_t raw_az = (buffer[4] << 8) | buffer[5];
+    int16_t raw_temp = (buffer[6] << 8) | buffer[7];
+    int16_t raw_gx = (buffer[8] << 8) | buffer[9];
+    int16_t raw_gy = (buffer[10] << 8) | buffer[11];
+    int16_t raw_gz = (buffer[12] << 8) | buffer[13];
+
+    float ax = (raw_ax / MPU6050_ACCEL_LSB_PER_G) * GRAVITY_M_S2;
+    float ay = (raw_ay / MPU6050_ACCEL_LSB_PER_G) * GRAVITY_M_S2;
+    float az = (raw_az / MPU6050_ACCEL_LSB_PER_G) * GRAVITY_M_S2;
+    float gx_deg_s = raw_gx / MPU6050_GYRO_LSB_PER_DEG_S;
+    float gy_deg_s = raw_gy / MPU6050_GYRO_LSB_PER_DEG_S;
+    float gz_deg_s = raw_gz / MPU6050_GYRO_LSB_PER_DEG_S;
+
    // Calculate time delta (dt) in seconds
    uint32_t now_us = micros();
    float dt = (now_us - last_update_us) / 1000000.0;  // Convert to seconds
@@ -111,22 +166,21 @@ bool IMU_Driver::update() {
    }

    // Store raw sensor data
-    data.accel_x = accel.acceleration.x;
-    data.accel_y = accel.acceleration.y;
-    data.accel_z = accel.acceleration.z;
-    data.gyro_x = gyro.gyro.x;
-    data.gyro_y = gyro.gyro.y;
-    data.gyro_z = gyro.gyro.z;
-    data.temperature = temp.temperature;
+    data.accel_x = ax;
+    data.accel_y = ay;
+    data.accel_z = az;
+    data.gyro_x = gx_deg_s * M_PI / 180.0;
+    data.gyro_y = gy_deg_s * M_PI / 180.0;
+    data.gyro_z = gz_deg_s * M_PI / 180.0;
+    data.temperature = (raw_temp / 340.0f) + 36.53f;
    data.timestamp = millis();

    // Calculate pitch and roll from accelerometer (gravity vector)
    float accel_pitch, accel_roll;
-    calculateAccelAngles(accel.acceleration.x, accel.acceleration.y, accel.acceleration.z,
-                        accel_pitch, accel_roll);
+    calculateAccelAngles(ax, ay, az, accel_pitch, accel_roll);

    // Apply complementary filter (fuse gyro + accel)
-    applyComplementaryFilter(accel_pitch, accel_roll, gyro.gyro.x, gyro.gyro.y, dt);
+    applyComplementaryFilter(accel_pitch, accel_roll, data.gyro_x, data.gyro_y, dt);

    // Apply calibration offsets
    data.pitch = constrainAngle(filtered_pitch - pitch_offset);
@@ -253,3 +307,39 @@ float IMU_Driver::constrainAngle(float angle) {
    while (angle < -180.0) angle += 360.0;
    return angle;
 }
+
+bool IMU_Driver::writeRegister(uint8_t reg, uint8_t value) {
+    wire->beginTransmission(IMU_I2C_ADDRESS);
+    wire->write(reg);
+    wire->write(value);
+    return wire->endTransmission() == 0;
+}
+
+bool IMU_Driver::readRegister(uint8_t reg, uint8_t &value) {
+    if (!readRegisters(reg, &value, 1)) {
+        return false;
+    }
+    return true;
+}
+
+bool IMU_Driver::readRegisters(uint8_t reg, uint8_t *buffer, size_t len) {
+    wire->beginTransmission(IMU_I2C_ADDRESS);
+    wire->write(reg);
+    if (wire->endTransmission(false) != 0) {
+        return false;
+    }
+
+    size_t received = wire->requestFrom((int)IMU_I2C_ADDRESS, (int)len, (int)true);
+    if (received != len) {
+        return false;
+    }
+
+    for (size_t i = 0; i < len; i++) {
+        if (!wire->available()) {
+            return false;
+        }
+        buffer[i] = wire->read();
+    }
+
+    return true;
+}
@@ -8,8 +8,6 @@

 #include <Arduino.h>
 #include <Wire.h>
-#include <Adafruit_MPU6050.h>
-#include <Adafruit_Sensor.h>

 // IMU data structure
 struct IMU_Data {
@@ -60,8 +58,8 @@ public:
    String getLastError() const;

 private:
-    // Adafruit MPU6050 driver instance
-    Adafruit_MPU6050 mpu;
+    // Active I2C bus for the IMU
+    TwoWire *wire;

    // Current IMU data
    IMU_Data data;
@@ -93,6 +91,11 @@ private:

    // Constrain angle to -180 to +180 range
    float constrainAngle(float angle);
+
+    // Low-level MPU6050 register access
+    bool writeRegister(uint8_t reg, uint8_t value);
+    bool readRegister(uint8_t reg, uint8_t &value);
+    bool readRegisters(uint8_t reg, uint8_t *buffer, size_t len);
 };

 #endif // IMU_DRIVER_H
@@ -107,7 +107,7 @@ void setup() {
    Serial.printf("[Setup] Master MAC: %02X:%02X:%02X:%02X:%02X:%02X\n",
                 master_mac[0], master_mac[1], master_mac[2],
                 master_mac[3], master_mac[4], master_mac[5]);
-    Serial.println("[Setup] **IMPORTANT**: Replace master_mac in config.h with your Master's MAC address!");
+    Serial.println("[Setup] Master MAC source: firmware/slave/src/config.cpp");
    #endif

    espnow = new ESPNowSlave(NODE_ID, master_mac);
@@ -115,7 +115,7 @@ void setup() {
    if (!espnow->begin()) {
        #ifdef DEBUG_SERIAL_ENABLED
        Serial.printf("[Setup] ERROR: ESP-NOW initialization failed: %s\n", espnow->getLastError().c_str());
-        Serial.println("[Setup] Check Master MAC address in config.h");
+        Serial.println("[Setup] Check Master MAC address in config.cpp");
        Serial.println("[Setup] HALTED - Cannot proceed without ESP-NOW");
        #endif

@@ -1,14 +1,19 @@
 # SkyLogic AeroAlign - 3D Printable Parts

-**Status**: Placeholder documentation for Phase 1 design
-**Design Tool**: FreeCAD 0.20+ (open-source parametric CAD)
-**Export Format**: STL for 3D printing
+**Status**: active documentation for AeroAlign plus planned CoG fixtures  
+**Design Tool**: FreeCAD 0.20+  
+**Export Format**: STL

 ---

 ## Overview

-This directory will contain all 3D printable parts for the SkyLogic AeroAlign wireless RC telemetry system. Parts are designed to fit within 200mm × 200mm × 200mm build volume (compatible with Ender 3, Prusa Mini, Bambu Lab P1P).
+This directory covers both halves of the project:
+
+- AeroAlign IMU housings and clips
+- future CoG scale fixtures and support cradles
+
+All parts should stay printable on common 200mm-class FDM printers.

 ---

@@ -47,7 +52,7 @@ This directory will contain all 3D printable parts for the SkyLogic AeroAlign wi
   - For 8mm thick control surfaces (large rudders, thicker wings)
   - Reinforced jaw design

-### Multi-Sensor Expansion (Phase 8)
+### Multi-Sensor Expansion / Future AeroAlign

 6. **wing_surface_mount_adjustable.stl**
   - 3-point contact clip for wing root attachment
@@ -76,6 +81,24 @@ This directory will contain all 3D printable parts for the SkyLogic AeroAlign wi
    - Variant of sensor_housing_top.stl with magnet pockets
    - 2× N52 neodymium magnets (10mm diameter × 2mm thick)

+### CoG Scale Fixtures (Planned)
+
+12. **cog_baseplate.stl**
+    - Flat base aligning front and rear supports
+    - Carries the support spacing reference
+
+13. **cog_support_front.stl**
+    - Front cradle above load cell #1
+    - Should include anti-slip contact pad area
+
+14. **cog_support_rear.stl**
+    - Rear cradle above load cell #2
+    - Matching geometry for repeatable support spacing
+
+15. **cog_hx711_mount.stl**
+    - Protected electronics bracket for HX711 boards
+    - Cable strain relief recommended
+
 ---

 ## Print Settings
@@ -155,13 +178,15 @@ This directory will contain all 3D printable parts for the SkyLogic AeroAlign wi

 ## Testing and Validation

-### Phase 2 Validation Tasks
+### Validation Tasks

 - [ ] T058: Print sensor housing on Ender 3 (verify fit and tolerance)
 - [ ] T059: Test print on Prusa Mini and Bambu Lab P1P (cross-printer compatibility)
 - [ ] T060: Create assembly guide with photos
 - [ ] T061: Document print settings for all STL files
 - [ ] T062: Weigh assembled nodes (verify <25g per node)
+- [ ] Validate CoG support rigidity under expected aircraft weights
+- [ ] Validate repeatable support spacing for CoG calculation

 ### Durability Testing

@@ -219,9 +244,9 @@ Under the following terms:

 ## Roadmap

-**Phase 1 (Current)**: Design sensor housing and basic clips
-**Phase 2**: Validate print quality on 3 printer brands
-**Phase 8**: Design specialized mounts for 8-sensor expansion
+**Current**: IMU housing and clips  
+**Next**: CoG baseplate and load-cell support fixtures  
+**Later**: integrated mixed-tool workshop kit

 ---

@@ -1,51 +1,19 @@
-Component,Description,Quantity per Node,Amazon ASIN (US),AliExpress Link,Unit Price (USD),Total Price (2 nodes),Notes,Alternatives
-ESP32-C3 DevKit,ESP32-C3 development board (RISC-V 160MHz WiFi/BLE),1,B09FK6F3JH,https://s.click.aliexpress.com/e/_DFKZXXX,$6.50,$13.00,"USB-C flashing ESP32-C3-DevKitM-1 or similar","ESP32-S3 (B0B6FF8K2M $12) for more power"
-MPU6050 IMU,6-axis IMU (gyro + accel I2C),1,B08F7PZHVT,https://s.click.aliexpress.com/e/_DEYYYY,$4.50,$9.00,"GY-521 module with voltage regulator","BNO055 (B08M3P1KQZ $12) for better accuracy"
-LiPo Battery 1S,250-400mAh 1S LiPo battery with JST connector,1,B0BKP6Y3XZ,https://s.click.aliexpress.com/e/_DFZZZZZ,$8.00,$16.00,"400mAh for Master 250mAh for Slave","500mAh (B08R3KZZZZ $9) for extended runtime"
-TP4056 Charger,USB-C LiPo charging module with protection,1,B09KGGZZZZ,https://s.click.aliexpress.com/e/_DKZZZZZ,$1.50,$3.00,"Type-C USB includes overcharge/discharge protection","Micro-USB version (B07KZZZZ $1.20)"
-HT7333 LDO,3.3V LDO voltage regulator (250mA),1,B07P6RZZZZ,https://s.click.aliexpress.com/e/_DLZZZZ,$0.80,$1.60,"SOT-89 package","AMS1117-3.3 (B01GZZZZ $0.50) if using through-hole"
-Neodymium Magnets,N52 10mm diameter × 2mm thick magnets (optional magnetic mount),2,B08LZZZZ,https://s.click.aliexpress.com/e/_DMZZZZ,$5.00,$10.00,"For magnetic quick-mount sensor housing","Adhesive Velcro strips (B07KZZZZ $4) alternative"
-3M VHB Tape,Double-sided adhesive tape for magnetic mount base,1 roll,B01MZZZZ,https://s.click.aliexpress.com/e/_DNZZZZ,$8.00,$8.00,"5m roll lasts for 50+ sensors","Gorilla tape (B06XZZZZ $6) cheaper alternative"
-Rubber Pads,Silicone anti-slip pads for clips (6mm diameter),6,B07TZZZZ,https://s.click.aliexpress.com/e/_DOZZZ,$3.00,$6.00,"Self-adhesive prevent surface scratches","EVA foam pads (B08KZZZZ $2.50)"
-M2 Screws,M2×6mm screws for housing assembly,4,B01MZZZZ (assortment),https://s.click.aliexpress.com/e/_DPZZZZ,$0.10,$0.40,"Stainless steel kit (500pcs)","M3 (B07ZZZZ) if using larger standoffs"
-JST Connector,JST-PH 2.0mm 2-pin connector for battery,1,B07QZZZZ,https://s.click.aliexpress.com/e/_DQZZZZ,$0.30,$0.60,"Male + female pair comes with most LiPos","XH2.54 (B08ZZZZ $0.40) if battery uses different connector"
-22AWG Wire,Silicone wire for battery/charging connections,0.5m,B07RZZZZ,https://s.click.aliexpress.com/e/_DRZZZZ,$0.50,$0.50,"Red + black stranded","24AWG (B06ZZZZ $0.40) also acceptable"
-Heat Shrink Tubing,Heat shrink tubing assortment,5cm,B08SZZZZ (assortment),https://s.click.aliexpress.com/e/_DSZZZZ,$0.10,$0.10,"3mm diameter for wire insulation","Electrical tape (B07ZZZZ $2) if no heat gun"
-10kΩ Resistor,10kΩ resistor for voltage divider (battery ADC),2,B08FZZZZ (assortment),https://s.click.aliexpress.com/e/_DTZZZZ,$0.05,$0.10,"1/4W through-hole carbon film","Resistor kit (B016ZZZZ $8) for 1000pcs"
-USB-C Cable,USB-C to USB-A cable for charging/flashing,1,B0BYZZZZ,https://s.click.aliexpress.com/e/_DUZZZZ,$4.00,$4.00,"1m length sufficient","USB-C to USB-C (B09ZZZZ $5) for newer laptops"
-,,,,,,,
-,,,,TOTAL (2 Sensors):,,$72.30,
-,,,,Master Node Only:,,$36.15,
-,,,,Slave Node Only:,,$36.15,
-,,,,,,
-,,,,4-Sensor System:,,$144.60,
-,,,,6-Sensor System:,,$216.90,
-,,,,8-Sensor System:,,$289.20,
-,,,,,,,
-Optional Upgrades,,,,,,,
-BNO055 IMU,9-axis IMU with sensor fusion (I2C),1,B08M3P1KQZ,https://s.click.aliexpress.com/e/_DVZZZZ,$12.00,$24.00,"±0.1° accuracy vs MPU6050 ±0.5°","MPU9250 (B07ZZZZ $8) if 9-axis needed"
-ESP32-S3 DevKit,ESP32-S3 dual-core 240MHz (8MB flash),1,B0B6FF8K2M,https://s.click.aliexpress.com/e/_DWZZZZ,$12.00,$24.00,"Faster web server response","ESP32-C3 sufficient for most users"
-500mAh LiPo,Larger battery for 6+ hour runtime,1,B08R3KZZZZ,https://s.click.aliexpress.com/e/_DXZZZZ,$9.00,$18.00,"Extends Master runtime to 6h","400mAh (default) provides 4h"
-,,,,,,,
-3D Printing Materials,,,,,,,
-PLA Filament,PLA filament for sensor housing (1kg),0.02kg,B07PZZZZ,https://s.click.aliexpress.com/e/_DYZZZZ,$20.00,$0.40,"~20g per node Black recommended","PETG (B08ZZZZ $25) for heat resistance"
-PETG Filament,PETG filament for flexible clips (1kg),0.01kg,B08ZZZZZ,https://s.click.aliexpress.com/e/_DAZZZZ,$25.00,$0.25,"~10g for 6 clips","TPU (B09ZZZZ $30) for maximum flexibility"
-,,,,,,,
-Tools Required (One-Time Purchase),,,,,,,
-Soldering Iron,Temperature-controlled soldering station,1,B08RZZZZ,https://s.click.aliexpress.com/e/_DBZZZZ,$25.00,$25.00,"Hakko FX-888D or similar","Basic iron (B06ZZZZ $15) acceptable"
-Solder Wire,60/40 tin-lead solder (0.8mm),1 roll,B07SZZZZ,https://s.click.aliexpress.com/e/_DCZZZZ,$8.00,$8.00,"Lead-free (B08ZZZZ $10) for EU compliance",
-Heat Gun,Heat gun for heat shrink tubing,1,B08TZZZZ,https://s.click.aliexpress.com/e/_DDZZZZ,$12.00,$12.00,"Or use lighter carefully","Mini heat gun (B07ZZZZ $8)"
-Wire Strippers,Wire stripper/cutter tool,1,B08UZZZZ,https://s.click.aliexpress.com/e/_DEZZZZ,$10.00,$10.00,"Automatic recommended","Manual (B06ZZZZ $6)"
-3D Printer,FDM 3D printer (200mm build volume),1,See notes,,,$200-500,"Ender 3 ($200) Prusa Mini ($400) Bambu P1P ($500)","Print service (3D Hubs) $10-20 per set"
-,,,,,,,
-TOTAL BOM (2-Sensor System):,,,,,$72.30,,"Competitive: GliderThrow $600 (8 sensors) SkyRC $80 (2 sensors)"
-TOTAL BOM (8-Sensor System):,,,,,$289.20,,"Our 8-sensor: $289 vs GliderThrow $600 (52% savings)"
-,,,,,,,
-Notes:,,,,,,,
- ASIN codes are placeholders (B0XXXXXX format) - verify current Amazon listings,,,,,,,
- Prices fluctuate ±20% based on seller and shipping,,,,,,,
- AliExpress links typically 30-50% cheaper but 2-4 week shipping,,,,,,,
- Total includes all components for 2 complete sensor nodes (Master + Slave),,,,,,,
- 3D printing materials cost negligible (~$0.65 per system),,,,,,,
- Tools are one-time purchase shared across projects,,,,,,,
- Multi-sensor systems (4/6/8 nodes) use same components multiplied,,,,,,,
+Category,Component,Description,Typical Qty,Used In,Notes
+Core MCU,ESP32-C3 DevKit,Low-cost main board,1 per node,"Master, IMU Slave, CoG Scale","Default low-cost choice"
+Core MCU,ESP32-S3 DevKit,Higher headroom alternative,1 per node,"Master, IMU Slave, CoG Scale","Useful for USB and future UI/diagnostics"
+IMU,MPU6050,GY-521 style 6-axis IMU,1 per IMU node,"Master, IMU Slave","Current robust driver implemented"
+Power,LiPo 1S,Portable battery pack,1 per portable node,"Master, IMU Slave, CoG Scale","Capacity depends on runtime target"
+Power,TP4056 USB-C,LiPo charger/protection board,1 per portable node,"Master, IMU Slave, CoG Scale","Optional for bench-powered scale jig"
+Power,3.3V regulator,Clean 3.3V supply,1 per portable node,"Master, IMU Slave, CoG Scale","Avoid noisy supply rails"
+Battery ADC,10k resistor,Voltage divider top resistor,1 per monitored node,"Master, IMU Slave","Use only where ADC monitoring is actually wired"
+Battery ADC,10k resistor,Voltage divider bottom resistor,1 per monitored node,"Master, IMU Slave","Master S3 currently optional"
+CoG Sensor,HX711,24-bit load cell ADC,2 per CoG scale,"CoG Scale","One per support recommended"
+CoG Sensor,Load cell,Single-point or suitable existing load cell,2 per CoG scale,"CoG Scale","Choose range for aircraft mass"
+Assembly,JST-PH 2.0,Battery connector,1 per battery node,"Master, IMU Slave, CoG Scale","Often already fitted to LiPo"
+Assembly,Wire,Signal and power wiring,as needed,"All","Keep I2C runs short"
+Assembly,Heat shrink,Insulation and strain relief,as needed,"All","Recommended for portable nodes"
+Mechanical,Sensor housing,3D printed IMU enclosure,1 per IMU node,"Master, IMU Slave","Existing AeroAlign style"
+Mechanical,Control surface clip,3D printed clip,1 per IMU node,"Master, IMU Slave","3 mm / 5 mm / 8 mm variants"
+Mechanical,Scale support cradle,3D printed support fixture,2 per CoG scale,"CoG Scale","To be designed"
+Mechanical,Scale base,3D printed baseplate,1 per CoG scale,"CoG Scale","To be designed"
+Reference,Known calibration mass,Weight for HX711 calibration,1 set,"CoG Scale","Needed for repeatable scale factors"
@@ -0,0 +1,131 @@
+# SkyLogic AeroAlign - CoG Scale Wiring
+
+**Version**: 0.1.0  
+**Date**: 2026-03-11  
+**Scope**: planned CoG scale node that shares the same Master and ESP-NOW fabric
+
+## Overview
+
+The CoG extension is based on two supports:
+
+- front support load cell
+- rear support load cell
+
+The recommended first implementation uses:
+
+- `1x ESP32-C3` or `1x ESP32-S3`
+- `2x HX711`
+- `2x single-point load cells` or your existing suitable load cells
+
+One HX711 per support keeps calibration and diagnostics simple.
+
+## Functional Model
+
+The CoG node reports three live values to the Master:
+
+- `front_weight_g`
+- `rear_weight_g`
+- `cog_position_mm`
+
+These values already fit the shared telemetry packet used by the current Master firmware.
+
+## Recommended Electronics
+
+| Part | Qty | Notes |
+|------|-----|-------|
+| ESP32-C3 or ESP32-S3 | 1 | same ecosystem as AeroAlign |
+| HX711 amplifier | 2 | one per support |
+| Load cell | 2 | typically 3 kg to 10 kg depending on model size |
+| LiPo or bench supply | 1 | portable or fixed jig |
+| TP4056 + regulator | optional | only for portable scale |
+
+## Wiring Strategy
+
+### HX711 #1: Front support
+
+| HX711 pin | Connection |
+|-----------|------------|
+| `VCC` | `3V3` |
+| `GND` | `GND` |
+| `DT` | `GPIO6` |
+| `SCK` | `GPIO7` |
+
+### HX711 #2: Rear support
+
+| HX711 pin | Connection |
+|-----------|------------|
+| `VCC` | `3V3` |
+| `GND` | `GND` |
+| `DT` | `GPIO8` |
+| `SCK` | `GPIO9` |
+
+These GPIOs are recommendations for the future CoG firmware. They are not yet hard-coded in the repo.
+
+## Load Cell Wiring
+
+Most 4-wire load cells expose:
+
+| Wire | Meaning |
+|------|---------|
+| Red | `E+` |
+| Black | `E-` |
+| Green | `A+` |
+| White | `A-` |
+
+Connect each load cell directly to one HX711.
+
+### Important
+
+Wire colors are not universal. Validate your load cells with the supplier datasheet or a multimeter before soldering.
+
+## Mechanical Layout
+
+```
+aircraft
+  |
+  +--> front support --> load cell #1 --> HX711 #1
+  |
+  +--> rear support  --> load cell #2 --> HX711 #2
+```
+
+The support spacing `L` must be known and entered into the system profile.
+
+## CoG Formula
+
+With front support at `x = 0` and rear support at `x = L`:
+
+`x_cog_from_front_support = rear_weight / (front_weight + rear_weight) * L`
+
+If you measure relative to the wing leading edge:
+
+`x_cog_from_leading_edge = support_offset_from_leading_edge + x_cog_from_front_support`
+
+## Calibration Plan
+
+Each support needs:
+
+1. zero / tare
+2. scale factor from known weight
+
+Recommended workflow:
+
+1. tare both supports empty
+2. place known weight on front support only
+3. save front factor
+4. repeat for rear support
+5. validate with known total weight centered between supports
+
+## Current Repo Status
+
+- shared protocol support exists in [telemetry_protocol.h](/Users/florianklaner/Github/AeroAlign/firmware/common/telemetry_protocol.h)
+- Master can already display CoG-style nodes in the existing UI
+- dedicated HX711 firmware is not implemented yet
+
+## Next Firmware Target
+
+Create a new node type, likely `firmware/cog_slave`, with:
+
+- HX711 reading
+- tare and scale calibration
+- CoG computation
+- ESP-NOW transmission using `DEVICE_TYPE_COG_SCALE`
@@ -1,360 +1,140 @@
-# SkyLogic AeroAlign - Sensor Node Wiring Diagram
+# SkyLogic AeroAlign - IMU Node Wiring

-**Version**: 1.0.0
-**Date**: 2026-01-22
-**Target Hardware**: ESP32-C3/ESP32-S3 + MPU6050 + LiPo + TP4056
-
---
+**Version**: 2.0.0  
+**Date**: 2026-03-11  
+**Scope**: Master and IMU slave nodes for the combined AeroAlign + CoG platform

 ## Overview

-This document describes the complete wiring schematic for both Master and Slave sensor nodes. Both nodes use identical wiring (Master additionally runs WiFi AP + web server in firmware).
+This document covers the current wiring for the angle-measurement nodes:

---
+- `Master`: ESP32-C3 or ESP32-S3, WiFi AP, web UI, ESP-NOW receiver, local IMU
+- `IMU Slave`: ESP32-C3 or ESP32-S3, remote MPU6050 node over ESP-NOW

-## Component List (Per Node)
+The Master and IMU Slave share the same MPU6050 wiring. The main difference is firmware role.  
+CoG-specific hardware is documented separately in [cog_scale_wiring.md](/Users/florianklaner/Github/AeroAlign/hardware/schematics/cog_scale_wiring.md).

-| Component | Part Number | Quantity | Function |
-|-----------|-------------|----------|----------|
-| ESP32-C3 DevKit | ESP32-C3-DevKitM-1 | 1 | Microcontroller |
-| MPU6050 IMU | GY-521 module | 1 | 6-axis motion sensor |
-| LiPo Battery | 1S 3.7V 250-400mAh | 1 | Power source |
-| TP4056 Charger | USB-C variant | 1 | Battery charging |
-| HT7333 LDO | 3.3V 250mA | 1 | Voltage regulator |
-| 10kΩ Resistor | 1/4W carbon film | 2 | Voltage divider for battery ADC |
-| JST Connector | 2-pin PH2.0 | 1 | Battery connector |
-| USB-C Cable | 1m | 1 | Charging/flashing |
+## Supported ESP32 Pin Maps

---
+### ESP32-C3

-## Power Supply Wiring
+| Signal | GPIO | Notes |
+|--------|------|-------|
+| `SDA` | `GPIO4` | MPU6050 I2C data |
+| `SCL` | `GPIO5` | MPU6050 I2C clock |
+| `BATTERY_ADC` | `GPIO0` | Battery divider midpoint |
+| `STATUS_LED` | `GPIO10` | Optional |
+
+### ESP32-S3
+
+| Signal | GPIO | Notes |
+|--------|------|-------|
+| `SDA` | `GPIO4` | MPU6050 I2C data |
+| `SCL` | `GPIO5` | MPU6050 I2C clock |
+| `BATTERY_ADC` | `GPIO1` | Only if divider is actually fitted |
+| `STATUS_LED` | disabled | Board-dependent, firmware keeps it off by default |
+
+## Power Topology

 ```
-LiPo Battery (3.7V nominal, 4.2V max, 3.0V min)
-    │
-    ├─► [+] TP4056 IN+  (Battery charging input)
-    │       TP4056 IN-  [GND]
-    │       TP4056 USB-C (for charging only)
-    │
-    └─► [+] HT7333 VIN  (3.0V - 4.2V input)
-            HT7333 GND  [GND]
-            HT7333 VOUT [3.3V] ─► ESP32-C3 3.3V pin
-                                  MPU6050 VCC
+LiPo 1S
+  |
+  +--> TP4056 BAT+/BAT-
+  |
+  +--> LDO VIN
+         |
+         +--> 3.3V rail --> ESP32 3V3
+                        --> MPU6050 VCC
 ```

-**Notes**:
- TP4056 charges LiPo when USB-C connected (red LED: charging, blue LED: full)
- HT7333 regulates LiPo voltage to stable 3.3V for ESP32 and IMU
- ESP32-C3 DevKit has built-in USB-C for programming (separate from TP4056 charging USB-C)
+### Notes

---
+- A dedicated 3.3V regulator is still recommended for clean IMU behavior.
+- The Master S3 configuration currently assumes battery monitoring may be absent.
+- If no ADC divider is wired on the Master, leave `BATTERY_MONITOR_ENABLED` disabled in [config.h](/Users/florianklaner/Github/AeroAlign/firmware/master/src/config.h).

-## ESP32-C3 to MPU6050 (I2C) Wiring
+## MPU6050 Wiring
+
+| ESP32 | MPU6050 | Notes |
+|-------|---------|-------|
+| `GPIO4` | `SDA` | I2C |
+| `GPIO5` | `SCL` | I2C |
+| `3V3` | `VCC` | Use 3.3V |
+| `GND` | `GND` | Common ground |
+| `GND` | `AD0` | Sets address `0x68` |
+
+### Bus Settings
+
+- ESP32-C3 default: `400 kHz`
+- ESP32-S3 default: `100 kHz`
+
+The lower S3 bus speed is intentional and matches the current robust MPU6050 access code.
+
+## Battery Divider
+
+Use the divider only on nodes that really need local battery reporting.

 ```
-ESP32-C3              MPU6050 (GY-521)
---------             ----------------
-GPIO4 (SDA) ───────► SDA (I2C Data)
-GPIO5 (SCL) ───────► SCL (I2C Clock)
-3.3V        ───────► VCC
-GND         ───────► GND
-                     INT (not connected)
-                     AD0 (GND for 0x68 address)
+LiPo+
+  |
+ [10k]
+  |
+  +----> BATTERY_ADC
+  |
+ [10k]
+  |
+ GND
 ```

-**I2C Configuration**:
- **Address**: 0x68 (default, AD0 pulled low)
- **Frequency**: 400kHz (fast mode)
- **Pull-ups**: Internal ESP32 pull-ups enabled (no external resistors needed)
+### Current firmware assumptions

-**Alternative**: BNO055 IMU (for ±0.1° accuracy upgrade)
-```
-ESP32-C3              BNO055
---------             ------
-GPIO4 (SDA) ───────► SDA
-GPIO5 (SCL) ───────► SCL
-3.3V        ───────► VIN
-GND         ───────► GND
-                     PS0 (GND for I2C mode)
-                     PS1 (3.3V)
-```
+- IMU slaves: divider enabled in firmware
+- Master C3: divider enabled
+- Master S3: divider disabled by default until the ADC path is actually wired

---
+## Master Node Wiring Summary

-## Battery Monitoring (Voltage Divider)
+| Block | Required | Notes |
+|-------|----------|-------|
+| ESP32-C3 or ESP32-S3 | yes | `master` firmware |
+| MPU6050 | yes | local reference IMU |
+| LiPo + charger + regulator | yes | portable operation |
+| Battery divider | optional | hidden in UI if absent |

-```
-LiPo+ (3.0V - 4.2V)
-    │
-    ▼
-   10kΩ Resistor (R1)
-    │
-    ├────► ESP32-C3 GPIO0 (ADC1_CH0)
-    │
-    ▼
-   10kΩ Resistor (R2)
-    │
-    └────► GND
+## IMU Slave Wiring Summary

-Output Voltage = (LiPo Voltage) / 2
-ESP32 ADC reads 0-1650mV (half of LiPo voltage)
-```
+| Block | Required | Notes |
+|-------|----------|-------|
+| ESP32-C3 or ESP32-S3 | yes | `slave` firmware |
+| MPU6050 | yes | same robust driver as Master |
+| LiPo + charger + regulator | yes | remote node |
+| Battery divider | recommended | transmitted to Master |

-**Calculation**:
-```cpp
-float adc_value = analogRead(GPIO0);  // 0-4095 (12-bit)
-float voltage_at_adc = (adc_value / 4095.0) * 3.3;  // Convert to volts
-float battery_voltage = voltage_at_adc * 2.0;  // Multiply by voltage divider ratio
-uint8_t battery_percent = ((battery_voltage - 3.0) / (4.2 - 3.0)) * 100.0;
-```
+## Bring-Up Checklist

-**Important**:
- R1 and R2 must be equal (10kΩ each) for 2:1 division
- ESP32-C3 ADC max input: 3.3V (do NOT exceed)
- LiPo max voltage 4.2V / 2 = 2.1V (safe margin)
-
---
-
-## Status LED (Optional)
-
-```
-ESP32-C3 GPIO10 ───► [+] LED [-] ───► 220Ω Resistor ───► GND
-```
-
-**LED Indicators**:
- **Solid Blue**: WiFi AP active (Master only)
- **Slow Blink (1Hz)**: Normal operation, connected
- **Fast Blink (5Hz)**: Searching for Master (Slave only)
- **Red Blink (3×)**: Low battery (<20%)
-
---
-
-## Complete Schematic (ASCII Art)
-
-```
-                    +──────────────────────────────────────+
-                    │      LiPo Battery (1S 3.7V)         │
-                    │         250-400mAh                   │
-                    +──────────────────────────────────────+
-                             │                  │
-                             │+                 │-
-                             │                  │
-                    ┌────────┴────────┐         │
-                    │   TP4056 Charger │         │
-USB-C Charge ───────┤   (USB-C input)  │         │
-                    │   OUT+       OUT-│         │
-                    └─────┬────────────┴─────────┤
-                          │+                    -│
-                          │                      │
-                    ┌─────┴──────────────────────┴─────┐
-                    │   HT7333 LDO Regulator           │
-                    │   VIN        GND        VOUT     │
-                    └──────────────┬───────────┬───────┘
-                                   │           │ 3.3V
-                                   │           │
-                     ┌─────────────┴───────────┴────────┐
-                     │      ESP32-C3 DevKit             │
-                     │                                  │
-     USB-C Flash ────┤ USB-C                            │
-                     │                                  │
-                     │  GPIO4 (SDA) ──────┐             │
-                     │  GPIO5 (SCL) ──────┤             │
-                     │  GPIO0 (ADC) ──────┤             │
-                     │  GPIO10 (LED) ─────┤             │
-                     │  3.3V ─────────────┤             │
-                     │  GND ──────────────┤             │
-                     └────────────────────┼─────────────┘
-                                          │
-                                          │
-                     ┌────────────────────┴─────────────┐
-                     │   MPU6050 IMU (GY-521)           │
-                     │                                  │
-                     │   SDA ◄──────────────────────────┤
-                     │   SCL ◄──────────────────────────┤
-                     │   VCC ◄───── 3.3V ───────────────┤
-                     │   GND ◄───── GND ────────────────┤
-                     │   INT (not connected)            │
-                     │   AD0 ◄───── GND (0x68 address)  │
-                     └──────────────────────────────────┘
-
-                         Battery Monitor (Voltage Divider)
-
-                     LiPo+ ──┬── 10kΩ ──┬── 10kΩ ── GND
-                             │          │
-                             │          └──► GPIO0 (ADC)
-                             │
-                         (Read half voltage)
-```
-
---
-
-## Pin Assignment Summary
-
-### ESP32-C3 GPIO Mapping
-
-| GPIO Pin | Function | Connection | Notes |
-|----------|----------|------------|-------|
-| GPIO0 | ADC1_CH0 | Battery voltage divider midpoint | Read battery level |
-| GPIO4 | I2C SDA | MPU6050 SDA | IMU data line |
-| GPIO5 | I2C SCL | MPU6050 SCL | IMU clock line |
-| GPIO10 | Digital Out | Status LED (optional) | Connection indicator |
-| 3.3V | Power | HT7333 VOUT, MPU6050 VCC | Regulated power rail |
-| GND | Ground | Common ground | All components share |
-| USB-C | USB Serial | Flashing/debugging | Built-in on DevKit |
-
-### MPU6050 (GY-521) Pinout
-
-| Pin | Function | Connection | Notes |
-|-----|----------|------------|-------|
-| VCC | Power | ESP32 3.3V | 3.3V or 5V compatible |
-| GND | Ground | Common GND | - |
-| SDA | I2C Data | GPIO4 | Pull-up enabled internally |
-| SCL | I2C Clock | GPIO5 | Pull-up enabled internally |
-| INT | Interrupt | Not used | Future: motion detection |
-| AD0 | Address Select | GND | Sets I2C address to 0x68 |
-
---
-
-## Assembly Instructions
-
-### Step 1: Solder HT7333 LDO
-
-1. **Identify pins**: HT7333 (SOT-89 package)
-   ```
-   ┌───────┐
-   │ HT7333│
-   └┬─┬─┬──┘
-    │ │ └── VOUT (3.3V output)
-    │ └──── GND
-    └────── VIN (3.0V-6.0V input)
-   ```
-
-2. Solder to TP4056 OUT+ (VIN) and OUT- (GND)
-3. Connect VOUT to ESP32-C3 3.3V rail
-
-### Step 2: Connect Battery
-
-1. Solder JST connector to LiPo (red = +, black = -)
-2. Connect to TP4056 BAT+ and BAT-
-3. **Important**: Check polarity before connecting!
-
-### Step 3: Wire I2C to MPU6050
-
-1. Solder 4 wires (SDA, SCL, VCC, GND) from ESP32-C3 to MPU6050
-2. Use 22AWG silicone wire (flexible, ~10cm length)
-3. Test continuity with multimeter
-
-### Step 4: Install Voltage Divider
-
-1. Solder two 10kΩ resistors in series
-2. Connect high end to LiPo+ (or TP4056 OUT+)
-3. Connect midpoint to ESP32-C3 GPIO0
-4. Connect low end to GND
-5. Cover with heat shrink tubing
-
-### Step 5: Test Power Supply
-
-1. **Without ESP32 connected**: Measure HT7333 VOUT with multimeter
-2. Expected: 3.25V-3.35V (3.3V ±50mV)
-3. If correct, connect ESP32-C3 3.3V pin
-
-### Step 6: Flash Firmware
-
-1. Connect ESP32-C3 USB-C to computer
-2. Flash Master or Slave firmware via PlatformIO
-3. Open serial monitor (115200 baud)
-4. Verify IMU initialization: "MPU6050 initialized (0x68)"
-
-### Step 7: Calibrate IMU
-
-1. Place sensor on flat, level surface
-2. Power on, wait 10 seconds for stabilization
-3. Web UI (Master) or serial output (Slave) should show ~0.0° pitch/roll
-
---
+1. Verify `3.3V` rail before plugging the ESP32 in.
+2. Confirm MPU6050 address `0x68` with `AD0` tied low.
+3. Keep SDA/SCL leads short on S3 builds.
+4. On the Slave, set the Master MAC in [config.cpp](/Users/florianklaner/Github/AeroAlign/firmware/slave/src/config.cpp).
+5. Build and flash:
+   - `cd firmware/master && pio run`
+   - `cd firmware/slave && pio run -e esp32-s3`

 ## Troubleshooting

-### Problem: ESP32 won't power on
+### No MPU6050 detected

-**Check**:
- LiPo voltage (should be 3.7V-4.2V)
- HT7333 VOUT (should be 3.3V)
- TP4056 protection (may shut down if overcharged/over-discharged)
+- Check `GPIO4` and `GPIO5`
+- Check `AD0 -> GND`
+- Reduce wire length
+- Prefer the S3 default `100 kHz`

-**Solution**: Charge LiPo via TP4056 USB-C
+### Battery percentage missing on Master

-### Problem: I2C not detected (MPU6050 not found)
+- Expected on S3 unless the divider is fitted and `BATTERY_MONITOR_ENABLED` is enabled
+- The web UI now hides the metric when unavailable

-**Check**:
- Wiring: SDA to GPIO4, SCL to GPIO5
- I2C address: Run I2C scanner (should show 0x68)
- Pull-ups: Enable internal pull-ups in firmware
+### Slave does not show up

-**Solution**: Verify connections, re-solder if cold joints
-
-### Problem: Battery percentage reads 0% or 255%
-
-**Check**:
- Voltage divider wiring (two 10kΩ resistors in series)
- ADC pin (GPIO0) connection to midpoint
- ADC code calibration (3.3V ADC reference)
-
-**Solution**: Measure voltage at GPIO0 with multimeter (should be LiPo voltage / 2)
-
-### Problem: IMU angles drift over time
-
-**Check**:
- Complementary filter alpha (should be 0.98)
- IMU temperature (MPU6050 sensitive to >15°C delta from calibration)
- Vibration isolation (sensor should be firmly mounted)
-
-**Solution**: Recalibrate at operating temperature, increase filter alpha to 0.99
-
---
-
-## Safety Warnings
-
-⚠️ **LiPo Battery Safety**:
- Never short-circuit LiPo terminals (fire/explosion risk)
- Do not charge above 4.2V (TP4056 prevents this)
- Do not discharge below 3.0V (TP4056 prevents this)
- Store at 50-60% charge (3.7V-3.8V) if unused >1 week
- Dispose of damaged/swollen batteries at hazardous waste facility
-
-⚠️ **Soldering Safety**:
- Use 300-350°C iron temperature (too hot damages components)
- Solder in ventilated area (avoid flux fumes)
- Do not touch soldering iron tip (obvious, but critical)
-
-⚠️ **ESD Protection**:
- ESP32-C3 and MPU6050 are ESD-sensitive
- Touch grounded metal before handling (discharge static)
- Avoid working on carpets or synthetic fabrics
-
---
-
-## Bill of Materials (Per Node)
-
-See `hardware/schematics/bom.csv` for complete BOM with Amazon ASINs and pricing.
-
-**Quick Summary**:
- ESP32-C3 DevKit: $6.50
- MPU6050 IMU: $4.50
- LiPo Battery (400mAh): $8.00
- TP4056 Charger: $1.50
- HT7333 LDO: $0.80
- Resistors, wire, connectors: $2.00
- **Total per node**: ~$23.30
-
---
-
-## Revision History
-
-| Version | Date | Changes |
-|---------|------|---------|
-| 1.0.0 | 2026-01-22 | Initial wiring diagram for MVP |
-
---
-
-*SkyLogic AeroAlign - Precision Grounded.*
+- Recheck Master MAC in [config.cpp](/Users/florianklaner/Github/AeroAlign/firmware/slave/src/config.cpp)
+- Ensure Master AP channel and ESP-NOW channel match