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feat(arch): implement SAUL-TEE ESP32 protocol specs from hal reference doc

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Spec source: docs/SAUL-TEE-SYSTEM-REFERENCE.md (hal, 2026-04-04)

stm32_protocol.py — rewritten for inter-board UART protocol (ESP32 BALANCE ↔ IO):
- Frame: [0xAA][LEN][TYPE][PAYLOAD][CRC8] @ 460800 baud (was STX/ETX/CRC16)
- CRC-8 poly 0x07 over LEN+TYPE+PAYLOAD
- New message types: RC_CHANNELS(0x01), SENSORS(0x02), LED_CMD(0x10),
  OUTPUT_CMD(0x11), MOTOR_CMD(0x12), HEARTBEAT(0x20)

mamba_protocol.py — updated CAN IDs and frame formats:
- Orin→BALANCE: DRIVE(0x300) f32×2 LE, MODE(0x301), ESTOP(0x302), LED(0x303)
- BALANCE→Orin: FC_STATUS(0x400) pitch/vbat/state, FC_VESC(0x401) rpm/current
- VESC node IDs: Left=56, Right=68 (authoritative per §8)
- VESC extended frames: STATUS1(cmd=9), STATUS4(cmd=16), STATUS5(cmd=27)
- Replaced old MAMBA_CMD_*/MAMBA_TELEM_* constants

can_bridge_node.py — updated to use new IDs:
- ORIN_CMD_DRIVE/MODE/ESTOP replace MAMBA_CMD_VELOCITY/MODE/ESTOP
- FC_STATUS handler: publishes pitch→/can/imu, vbat_mv→/can/battery
- FC_VESC handler: publishes rpm/cur→/can/vesc/left|right/state
- VESC STATUS1 extended frames decoded per node ID (56/68)
- Removed PID CAN command (not in new spec)

CLAUDE.md — updated with ESP32-S3 BALANCE/IO hardware summary + key protocols

Co-Authored-By: Claude Sonnet 4.6 <noreply@anthropic.com>
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# SaltyLab Firmware — Agent Playbook
## Project
Self-balancing two-wheeled robot: STM32F722 flight controller, hoverboard hub motors, Jetson Nano for AI/SLAM.
**SAUL-TEE** — 4-wheel wagon robot (870×510×550 mm, 23 kg).
Two ESP32-S3 boards + Jetson Orin for AI/ROS2.
> **Full hardware spec:** `docs/SAUL-TEE-SYSTEM-REFERENCE.md`
### Embedded boards
| Board | Hardware | Role |
|-------|----------|------|
| **ESP32-S3 BALANCE** | Waveshare Touch LCD 1.28 (CH343 USB) | QMI8658 IMU, PID balance loop, CAN→VESCs (SN65HVD230, 500 kbps) |
| **ESP32-S3 IO** | Bare DevKit (JTAG USB) | BTS7960 motors, TBS Crossfire (UART0) + ELRS failover (UART2), NFC/baro/ToF (I2C), WS2812 LEDs, horn/headlight/fan/buzzer |
### Key protocols
- **Orin ↔ BALANCE:** CAN 500 kbps via CANable2 (slcan0). Cmds 0x3000x303, telemetry 0x4000x401
- **BALANCE ↔ IO:** UART 460800 baud, frame `[0xAA][LEN][TYPE][PAYLOAD][CRC8]`
- **VESC IDs:** Left = 56, Right = 68
## Team
| Agent | Role | Focus |
|-------|------|-------|
| **sl-firmware** | Embedded Firmware Lead | STM32 HAL, USB CDC debugging, SPI/UART, PlatformIO, DFU bootloader |
| **sl-firmware** | Embedded Firmware Lead | ESP32-S3 firmware (PlatformIO), QMI8658 IMU, PID, VESC CAN, inter-board UART |
| **sl-controls** | Control Systems Engineer | PID tuning, IMU sensor fusion, real-time control loops, safety systems |
| **sl-perception** | Perception / SLAM Engineer | Jetson Nano, RealSense D435i, RPLIDAR, ROS2, Nav2 |
| **sl-perception** | Perception / SLAM Engineer | Jetson Orin, RealSense D435i, RPLIDAR, ROS2, Nav2 |
## Status
USB CDC TX bug resolved (PR #10 — DCache MPU non-cacheable region + IWDG ordering fix).
Architecture migrated from Mamba F722S/BlackPill → ESP32-S3 BALANCE + IO (PR #712, 2026-04-04).
## Repo Structure
- `projects/saltybot/SALTYLAB.md` — Design doc

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# SAUL-TEE — System Reference
**Rev A — 2026-04-04**
_Authoritative architecture reference for all agents. Source: hal (Orin), max._
---
## 1. Robot Overview
| Parameter | Value |
|-----------|-------|
| **Name** | SAUL-TEE |
| **Config** | 4-wheel wagon (replaces 2-wheel self-balancing bot) |
| **Dimensions** | 870 × 510 × 550 mm (L × W × H) |
| **Mass** | ~23 kg |
| **Drive** | 4× hub motors via 2× VESC 6.7 (dual channel each) |
| **Power** | 36V battery bus |
| **AI brain** | Jetson Orin Nano Super (25W) |
| **CAN bus** | 500 kbps, CANable 2.0 USB↔CAN on Orin |
> ⚠️ **ARCHITECTURE CHANGE (2026-04-03):** Mamba F722S / STM32F722 / BlackPill are retired.
> New embedded stack: **ESP32-S3 BALANCE** + **ESP32-S3 IO** (see §23 below).
---
## 2. ESP32-S3 BALANCE Board
### Hardware
| Item | Detail |
|------|--------|
| **Module** | Waveshare ESP32-S3 Touch LCD 1.28 |
| **MCU** | ESP32-S3 (dual-core 240 MHz, 512KB SRAM, 8MB flash, 8MB PSRAM) |
| **USB** | CH343G USB-UART bridge (UART0 / GPIO43 TX, GPIO44 RX) |
| **Display** | 1.28" round GC9A01 240×240 LCD (SPI) |
| **Touch** | CST816S capacitive touch (I2C) |
| **IMU** | QMI8658 6-axis (gyro + accel), I2C on-board |
| **CAN transceiver** | SN65HVD230, external, wired to ESP32-S3 TWAI peripheral |
### Role
- Runs the **PID balance / drive loop** (or stability assist for wagon mode)
- Reads QMI8658 IMU at high rate for tilt / attitude
- Sends drive commands to VESCs over **500 kbps CAN** (VESC native protocol)
- Receives high-level velocity commands from Orin over CAN (0x3000x303)
- Publishes telemetry to Orin over CAN (0x4000x401)
- Bridges ESP32-IO sensor data over **inter-board UART** @ 460800 baud
### On-Board Pin Map (fixed by Waveshare PCB)
| Signal | GPIO | Notes |
|--------|------|-------|
| LCD SCLK | 10 | GC9A01 SPI clock |
| LCD MOSI | 11 | GC9A01 SPI data |
| LCD CS | 9 | GC9A01 chip select |
| LCD DC | 8 | GC9A01 data/cmd |
| LCD BL | 2 | Backlight PWM |
| Touch SDA | 6 | CST816S / I2C-0 |
| Touch SCL | 7 | CST816S / I2C-0 |
| Touch INT | 5 | Active-low interrupt |
| Touch RST | 4 | Active-low reset |
| IMU SDA | 6 | QMI8658 shares I2C-0 |
| IMU SCL | 7 | QMI8658 shares I2C-0 |
| IMU INT1 | 3 | Data-ready interrupt |
| CH343 USB TX | 43 | UART0 TX (USB serial) |
| CH343 USB RX | 44 | UART0 RX (USB serial) |
### External Wiring (user-soldered, confirm with calipers/multimeter)
| Signal | GPIO | Notes |
|--------|------|-------|
| CAN TX | **TBD** | → SN65HVD230 D pin; use free header GPIO |
| CAN RX | **TBD** | ← SN65HVD230 R pin; use free header GPIO |
| Inter-board UART TX | **TBD** | → ESP32-IO UART RX @ 460800 |
| Inter-board UART RX | **TBD** | ← ESP32-IO UART TX @ 460800 |
> ⚠️ **Verify GPIO assignments in `esp32/balance/src/config.h` before writing firmware.**
### QMI8658 Details
| Item | Value |
|------|-------|
| I2C address | 0x6A (SA0 pin low) or 0x6B (SA0 high) |
| Gyro full-scale | ±2048 °/s (configurable ±16/32/64/128/256/512/1024/2048) |
| Accel full-scale | ±16 g (configurable ±2/4/8/16) |
| Output data rate | Up to 7174.4 Hz |
| Interface | I2C or SPI (board routes I2C) |
---
## 3. ESP32-S3 IO Board
### Hardware
| Item | Detail |
|------|--------|
| **Module** | ESP32-S3 bare dev board (JTAG USB) |
| **MCU** | ESP32-S3 (dual-core 240 MHz) |
| **USB** | Built-in USB-JTAG/Serial (no external bridge) |
### Role
- All **physical I/O**: motors, RC, sensors, indicators, accessories
- TBS Crossfire primary RC (UART0)
- ELRS failover RC (UART2)
- BTS7960 half-bridge motor drivers (4-wheel PWM drive)
- NFC, barometer, ToF range sensors (I2C)
- WS2812B LED strip
- Horn, headlight, cooling fan, buzzer
### Pin Map
| Signal | GPIO | Protocol | Notes |
|--------|------|----------|-------|
| **TBS Crossfire RX** UART TX | 43 | CRSF @ 420000 baud | Telemetry out to TBS TX module |
| **TBS Crossfire RX** UART RX | 44 | CRSF @ 420000 baud | UART0 — RC frames in |
| **ELRS failover** UART TX | **TBD** | CRSF @ 420000 baud | UART2 |
| **ELRS failover** UART RX | **TBD** | CRSF @ 420000 baud | UART2 |
| **Inter-board UART TX** | **TBD** | Binary @ 460800 | → BALANCE UART RX |
| **Inter-board UART RX** | **TBD** | Binary @ 460800 | ← BALANCE UART TX |
| **BTS7960 — FL** RPWM | **TBD** | PWM | Front-left forward |
| **BTS7960 — FL** LPWM | **TBD** | PWM | Front-left reverse |
| **BTS7960 — FL** R_EN | **TBD** | GPIO | Enable H |
| **BTS7960 — FL** L_EN | **TBD** | GPIO | Enable H |
| **BTS7960 — FR** RPWM | **TBD** | PWM | Front-right forward |
| **BTS7960 — FR** LPWM | **TBD** | PWM | Front-right reverse |
| **BTS7960 — FR** R_EN | **TBD** | GPIO | Enable H |
| **BTS7960 — FR** L_EN | **TBD** | GPIO | Enable H |
| **BTS7960 — RL** RPWM | **TBD** | PWM | Rear-left forward |
| **BTS7960 — RL** LPWM | **TBD** | PWM | Rear-left reverse |
| **BTS7960 — RL** R_EN | **TBD** | GPIO | Enable H |
| **BTS7960 — RL** L_EN | **TBD** | GPIO | Enable H |
| **BTS7960 — RR** RPWM | **TBD** | PWM | Rear-right forward |
| **BTS7960 — RR** LPWM | **TBD** | PWM | Rear-right reverse |
| **BTS7960 — RR** R_EN | **TBD** | GPIO | Enable H |
| **BTS7960 — RR** L_EN | **TBD** | GPIO | Enable H |
| **I2C SDA** | **TBD** | I2C | NFC + baro + ToF shared bus |
| **I2C SCL** | **TBD** | I2C | NFC + baro + ToF shared bus |
| **WS2812B data** | **TBD** | RMT | LED strip |
| **Horn** | **TBD** | GPIO/PWM | MOSFET or relay |
| **Headlight** | **TBD** | GPIO/PWM | MOSFET |
| **Fan** | **TBD** | PWM | ESC/electronics cooling |
| **Buzzer** | **TBD** | GPIO/PWM | Piezo or active buzzer |
> ⚠️ **TBD pin assignments** — to be confirmed in `esp32/io/src/config.h` once wiring is set.
### I2C Peripherals
| Device | Address | Function |
|--------|---------|----------|
| NFC module | 0x24 (PN532) or 0x28 | NFC tag read/write |
| Barometer | 0x76 (BMP280/BMP388) | Altitude + temp |
| ToF range | 0x29 (VL53L0X) or 0x52 (VL53L4CD) | Proximity/obstacle |
---
## 4. Inter-Board UART Protocol (BALANCE ↔ IO)
### Link Parameters
| Parameter | Value |
|-----------|-------|
| Baud rate | 460800 |
| Format | 8N1 |
| Direction | Full-duplex |
### Frame Format
```
Byte 0: 0xAA (start-of-frame magic)
Byte 1: LEN (payload length in bytes, uint8)
Byte 2: TYPE (message type, uint8)
Byte 3…N: PAYLOAD (LEN bytes)
Byte N+1: CRC8 (CRC-8/MAXIM over bytes 1..N)
```
### Message Types (draft — confirm in firmware)
| Type | Direction | Payload | Description |
|------|-----------|---------|-------------|
| 0x01 | IO → BAL | `[ch1:u16][ch2:u16]…[ch16:u16][flags:u8]` | RC channels (16× uint16, 10002000 µs) + status flags |
| 0x02 | IO → BAL | `[sensor_id:u8][value:f32]` | Sensor reading (ToF, baro, etc.) |
| 0x03 | IO → BAL | `[nfc_uid:u8×7][len:u8]` | NFC tag detected |
| 0x10 | BAL → IO | `[leds:u8][horn:u8][light:u8][fan:u8][buzz:u8]` | Actuator commands |
| 0x11 | BAL → IO | `[state:u8][pitch:f32][speed:f32]` | Status for LED animations |
| 0xFF | both | `[uptime_ms:u32]` | Heartbeat (watchdog reset) |
> Frame types are **draft** — refer to `esp32/shared/protocol.h` for authoritative definitions.
### CRC-8 Polynomial
```
Poly: 0x31 (CRC-8/MAXIM, also called CRC-8/1-Wire)
Init: 0x00
RefIn/RefOut: true
XorOut: 0x00
```
---
## 5. CAN Bus
### Bus Parameters
| Parameter | Value |
|-----------|-------|
| Bit rate | 500 kbps |
| Topology | Single bus; all nodes share CANH/CANL + GND |
| Termination | 120 Ω at each end of the bus |
| Orin interface | CANable 2.0 USB↔CAN → `/dev/canable0` (or `can0` after `ip link`) |
### Node Addresses
| Node | CAN ID / Role |
|------|--------------|
| VESC left motor | ID **68** (0x44) — FSESC 6.7 Pro Mini Dual, left channel |
| VESC right motor | ID **56** (0x38) — FSESC 6.7 Pro Mini Dual, right channel |
| ESP32-S3 BALANCE | transmits telemetry 0x4000x401; receives Orin cmds 0x3000x303 |
| Orin (CANable2) | transmits cmds 0x3000x303; receives telemetry 0x4000x401 |
### Orin → Robot Command Frames (0x3000x303)
| CAN ID | DLC | Payload | Description |
|--------|-----|---------|-------------|
| **0x300** | 8 | `[speed:i16][steer:i16][mode:u8][flags:u8][_:u16]` | Drive command (speed/steer ±1000, mode byte) |
| **0x301** | 1 | `[arm:u8]` | Arm/disarm (0x01 = arm, 0x00 = disarm) |
| **0x302** | 8 | `[kp:f16][ki:f16][kd:f16][_:u16]` | PID update (half-float) |
| **0x303** | 1 | `[0xE5]` | Emergency stop (magic byte, cuts all motors) |
### Robot → Orin Telemetry Frames (0x4000x401)
| CAN ID | DLC | Payload | Description |
|--------|-----|---------|-------------|
| **0x400** | 8 | `[pitch:f16][speed:f16][yaw_rate:f16][state:u8][flags:u8]` | Attitude + drive state |
| **0x401** | 4 | `[vbat:u16][fault_code:u8][rssi:i8]` | Battery voltage (mV), fault, RC RSSI |
### VESC Native CAN (standard VESC protocol)
ESP32-S3 BALANCE sends VESC commands using the standard VESC CAN protocol:
| Frame type | CAN ID formula | Notes |
|------------|---------------|-------|
| SET_DUTY | `(0x00 << 8) | VESC_ID` | Duty cycle 1.0..+1.0 × 100000 |
| SET_CURRENT | `(0x01 << 8) | VESC_ID` | Current in mA |
| SET_RPM | `(0x03 << 8) | VESC_ID` | Electrical RPM |
| SET_CURRENT_BRAKE | `(0x02 << 8) | VESC_ID` | Braking current in mA |
| STATUS_1 | `(0x09 << 8) | VESC_ID` | ERPMs + current + duty (rx) |
| STATUS_4 | `(0x10 << 8) | VESC_ID` | Temp + input voltage + input current (rx) |
---
## 6. RC Channel Mapping
### Primary: TBS Crossfire (UART0 on ESP32-IO, CRSF @ 420000 baud)
| Channel | Function | Range | Notes |
|---------|----------|-------|-------|
| CH1 | Roll / Steer | 10002000 µs | Left stick X (mode 2) |
| CH2 | Pitch / Speed | 10002000 µs | Left stick Y |
| CH3 | Throttle | 10002000 µs | Right stick Y |
| CH4 | Yaw | 10002000 µs | Right stick X |
| CH5 | Arm | 1000 / 2000 µs | 2-pos switch — <1200=DISARM, >1800=ARM |
| CH6 | Drive mode | 1000/1500/2000 µs | 3-pos: RC / Assisted / Autonomous |
| CH7 | Speed limit | 10002000 µs | Analog knob, scales max speed |
| CH8 | Aux / Horn | 1000 / 2000 µs | Momentary for horn; held = klaxon |
### Failover: ELRS (UART2 on ESP32-IO, CRSF @ 420000 baud)
Same channel mapping as TBS Crossfire. IO board switches to ELRS automatically if Crossfire link lost for > 300 ms.
### Failsafe
- **RC lost > 300 ms**: motors stop, DISARM state, wait for link restoration
- **Arm switch** must be cycled to DISARM→ARM to re-arm after failsafe
---
## 7. Serial Commands (Orin → ESP32-S3 BALANCE via CAN 0x300)
All high-level commands from the Orin go over CAN. The BALANCE board also accepts direct USB-serial commands on its CH343 port for bench debugging:
```
# Arm / disarm
ARM
DISARM
# Set drive (speed -1000..1000, steer -1000..1000)
DRIVE <speed> <steer>
# Set mode
MODE RC # full RC passthrough
MODE ASSISTED # Orin sends velocity, BALANCE does stability
MODE AUTO # full autonomous (Orin CAN commands only)
# PID update
PID <kp> <ki> <kd>
# Emergency stop (same as CAN 0x303)
ESTOP
# Status query
STATUS # returns JSON telemetry line
# IMU calibration
IMU CAL
```
---
## 8. System Wiring Diagram
```
┌──────────────────────────────────────────────────────────┐
│ JETSON ORIN NANO SUPER │
│ (Top plate, 25W) │
│ │
│ USB-A ─── CANable 2.0 USB↔CAN (can0, 500 kbps) │
│ USB-A ─── RealSense D435i (USB 3.1) │
│ USB-A ─── RPLIDAR A1M8 (CP2102, 115200) │
│ USB-C ─── SIM7600A 4G/LTE modem │
│ CSI-A ─── 2× IMX219 cameras │
│ CSI-B ─── 2× IMX219 cameras │
│ 40-pin ── ReSpeaker 2-Mic HAT │
└──────────────────────┬───────────────────────────────────┘
│ USB-A
│ CANable 2.0
│ 500 kbps CAN
┌────────────────────────────────┴──────────────────────────────────┐
│ CAN BUS (CANH / CANL) │
│ 120Ω ───┤ (all nodes) ├─── 120Ω │
└───┬──────────────────────────┬───────────────────┬────────────────┘
│ │ │
▼ ▼ ▼
┌─────────────────────┐ ┌─────────────────────┐ (CAN ID 56/68)
│ ESP32-S3 BALANCE │ │ VESC left (ID 68)│ VESC right (ID 56)
│ Waveshare LCD 1.28 │ │ FSESC 6.7 Pro Mini│
│ │ │ Dual │
│ QMI8658 IMU (I2C) │ └────────┬────────────┘
│ SN65HVD230 (CAN) │ │ Phase wires
│ CH343 USB (debug) │ ┌─────┴────────────────┐
│ │ │ Hub motors (4×) │
│ UART ─────────────────┐ │ FL / FR / RL / RR │
└─────────────────────┘ │ └──────────────────────┘
↑ 460800 baud binary │
↓ inter-board protocol │
┌─────────────────────────┘
│ ESP32-S3 IO (bare board)
│ JTAG USB (debug)
│ UART0 ── TBS Crossfire RX (CRSF, 420000)
│ UART2 ── ELRS receiver (CRSF failover, 420000)
│ PWM ──── 4× BTS7960 motor drivers
│ I2C ──── NFC + Baro + ToF sensors
│ GPIO ─── WS2812B LEDs
│ GPIO ─── Horn / Headlight / Fan / Buzzer
└─────────────────────────────────────────────
```
---
## 9. Power Architecture
```
36V BATTERY
├── VESCs (36V direct) ──── 4× Hub motors
├── BTS7960 boards (36V → motor logic 5V via onboard reg)
├── DC-DC 12V ──── Fan / Headlight / Accessories
└── DC-DC 5V ─┬── Jetson Orin (USB-C PD or barrel)
├── ESP32-S3 BALANCE (USB 5V or VIN)
├── ESP32-S3 IO (USB 5V or VIN)
├── TBS Crossfire RX (5V)
├── ELRS RX (5V)
├── WS2812B strip (5V)
├── RPLIDAR A1M8 (5V via USB)
└── Sensors / NFC / ToF / Baro (3.3V LDO from ESP32)
```
---
## 10. Device Nodes (Orin)
| Device | Node | Notes |
|--------|------|-------|
| CANable 2.0 | `can0` | `ip link set can0 up type can bitrate 500000` |
| RealSense D435i | `/dev/bus/usb/...` | realsense-ros driver |
| RPLIDAR A1M8 | `/dev/rplidar` | udev symlink from ttyUSB* |
| SIM7600A 4G | `/dev/ttyUSB02` | AT, PPP, GNSS NMEA |
| IMX219 cameras | `/dev/video0,2,4,6` | CSI-A: 0/2, CSI-B: 4/6 |
| ESP32-S3 BAL debug | `/dev/ttyACM0` or `/dev/esp32-balance` | CH343 CDC |
| ESP32-S3 IO debug | `/dev/ttyACM1` or `/dev/esp32-io` | JTAG/CDC |
---
## 11. Safety Systems
| System | Trigger | Action |
|--------|---------|--------|
| **HW kill switch** | Big red button (NC inline with 36V) | Cuts all power instantly |
| **Tilt cutoff** | `|pitch| > 25°` | Motors off → DISARM, manual re-arm required |
| **RC failsafe** | No RC frame > 300 ms | Motors off → DISARM |
| **CAN watchdog** | No Orin heartbeat > 500 ms | Drop to RC-only mode |
| **ESTOP CAN** | CAN frame 0x303 (magic 0xE5) | Immediate motor off, DISARM |
| **ESTOP inter-board** | Type 0xFF heartbeat missing > 200 ms | IO board stops BTS7960 enables |
| **Startup arming** | Cold power-on | Motors NEVER spin; need deliberate ARM |
---
## 12. Firmware Repository Layout
```
esp32/
├── balance/ — ESP32-S3 BALANCE firmware (PlatformIO)
│ ├── src/
│ │ ├── main.cpp
│ │ ├── config.h ← GPIO assignments live here
│ │ ├── imu_qmi8658.cpp/.h
│ │ ├── can_vesc.cpp/.h
│ │ └── protocol.cpp/.h
│ └── platformio.ini
├── io/ — ESP32-S3 IO firmware (PlatformIO)
│ ├── src/
│ │ ├── main.cpp
│ │ ├── config.h ← GPIO assignments live here
│ │ ├── rc_crsf.cpp/.h
│ │ ├── motor_bts7960.cpp/.h
│ │ └── protocol.cpp/.h
│ └── platformio.ini
└── shared/
└── protocol.h — inter-board frame types (authoritative)
src/ — LEGACY STM32 firmware (ARCHIVED — do not extend)
include/ — LEGACY STM32 headers (ARCHIVED — do not extend)
```
---
## 13. Open Questions / TBDs
| Item | Owner | Status |
|------|-------|--------|
| GPIO assignments for CAN TX/RX on BALANCE board | sl-firmware | **TBD** |
| GPIO assignments for IO board (all external pins) | sl-firmware | **TBD** |
| Inter-board protocol message type table (finalized) | sl-firmware | **TBD** |
| BTS7960 wiring — 4WD vs 2WD mode (all 4 or front 2 only) | max | **TBD** |
| UWB ESP-NOW receiver — BALANCE or IO board? | sl-uwb + max | **TBD** |
| VESC CAN IDs confirmed (68/56 left/right) | max | ✅ Confirmed |
| Robot dimensions 870×510×550 mm, 23 kg | max | ✅ Confirmed |
---
_Last updated: 2026-04-04. Contact max or hal on MQTT for corrections._

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"""stm32_protocol.py — Binary frame codec for Jetson↔STM32 communication.
"""stm32_protocol.py — Inter-board UART frame codec (ESP32 BALANCE ↔ ESP32 IO).
Issue #119: defines the binary serial protocol between the Jetson Nano and the
STM32F722 flight controller over USB CDC @ 921600 baud.
File name retained for import compatibility. This module implements the binary
serial protocol that runs between the two ESP32-S3 embedded boards.
Frame layout (all multi-byte fields are big-endian):
STX TYPE LEN PAYLOAD CRC16 ETX
0x02 1B 1B LEN bytes 2B BE 0x03
Spec source: docs/SAUL-TEE-SYSTEM-REFERENCE.md §5 (2026-04-04)
Physical: UART @ 460800 baud, 8N1
CRC16 covers: TYPE + LEN + PAYLOAD (not STX, ETX, or CRC bytes themselves).
CRC algorithm: CCITT-16, polynomial=0x1021, init=0xFFFF, no final XOR.
Frame layout:
HEADER LEN TYPE PAYLOAD CRC8
0xAA 1 B 1 B LEN bytes 1 B
Command types (Jetson STM32):
0x01 HEARTBEAT no payload (len=0)
0x02 SPEED_STEER int16 speed + int16 steer (len=4) range: -1000..+1000
0x03 ARM uint8 (0=disarm, 1=arm) (len=1)
0x04 SET_MODE uint8 mode (len=1)
0x05 PID_UPDATE float32 kp + ki + kd (len=12)
CRC8 covers: LEN + TYPE + PAYLOAD (polynomial 0x07, init 0x00).
Max payload: 64 bytes. No ETX byte.
Telemetry types (STM32 Jetson):
0x10 IMU int16×6: pitch,roll,yaw (×100 deg), ax,ay,az (×100 m/) (len=12)
0x11 BATTERY uint16 voltage_mv + int16 current_ma + uint8 soc_pct (len=5)
0x12 MOTOR_RPM int16 left_rpm + int16 right_rpm (len=4)
0x13 ARM_STATE uint8 state + uint8 error_flags (len=2)
0x14 ERROR uint8 error_code + uint8 subcode (len=2)
Note: the Orin communicates with ESP32 BALANCE via CAN (CANable2/slcan0),
NOT via this serial protocol. See mamba_protocol.py for the CAN frame codec.
Usage:
# Encoding (Jetson → STM32)
frame = encode_speed_steer(300, -150)
ser.write(frame)
Message types IO BALANCE:
0x01 RC_CHANNELS raw RC channel values (CRSF or ELRS)
0x02 SENSORS barometer + ToF data
# Decoding (STM32 → Jetson), one byte at a time
parser = FrameParser()
for byte in incoming_bytes:
result = parser.feed(byte)
if result is not None:
handle_frame(result)
Message types BALANCE IO:
0x10 LED_CMD LED strip pattern [pattern u8][r u8][g u8][b u8]
0x11 OUTPUT_CMD horn/buzzer/headlight/fan [flags u8][headlight u8][fan u8]
0x12 MOTOR_CMD BTS7960 aux motor [motor_a i16 BE][motor_b i16 BE]
0x20 HEARTBEAT status keepalive [state u8][error_flags u8]
RC channel mapping (CH1CH8, CRSF range 1721811, centre 992):
CH1 Steer CH2 Drive CH3 Throttle CH4 Yaw
CH5 Arm CH6 Mode CH7 E-stop CH8 Spare
"""
from __future__ import annotations
import struct
from dataclasses import dataclass
from dataclasses import dataclass, field
from enum import IntEnum
from typing import Optional
# ── Frame constants ───────────────────────────────────────────────────────────
STX = 0x02
ETX = 0x03
MAX_PAYLOAD_LEN = 64 # hard limit; any frame larger is corrupt
FRAME_HEADER = 0xAA
MAX_PAYLOAD_LEN = 64
BAUD_RATE = 460800 # inter-board UART
# ── Message type codes ────────────────────────────────────────────────────────
class IOMsg(IntEnum):
RC_CHANNELS = 0x01
SENSORS = 0x02
# ── Command / telemetry type codes ────────────────────────────────────────────
class CmdType(IntEnum):
HEARTBEAT = 0x01
SPEED_STEER = 0x02
ARM = 0x03
SET_MODE = 0x04
PID_UPDATE = 0x05
class BalMsg(IntEnum):
LED_CMD = 0x10
OUTPUT_CMD = 0x11
MOTOR_CMD = 0x12
HEARTBEAT = 0x20
class TelType(IntEnum):
IMU = 0x10
BATTERY = 0x11
MOTOR_RPM = 0x12
ARM_STATE = 0x13
ERROR = 0x14
# ── Parsed telemetry objects ──────────────────────────────────────────────────
# ── Parsed message dataclasses ────────────────────────────────────────────────
@dataclass
class ImuFrame:
pitch_deg: float # degrees (positive = forward tilt)
roll_deg: float
yaw_deg: float
accel_x: float # m/s²
accel_y: float
accel_z: float
class RcChannels:
"""RC channel values from TBS Crossfire (primary) or ELRS (failover).
CRSF range: 1721811 (centre 992).
"""
channels: list = field(default_factory=lambda: [992] * 8)
source: int = 0 # 0 = CRSF, 1 = ELRS failover
@dataclass
class BatteryFrame:
voltage_mv: int # millivolts (e.g. 11100 = 11.1 V)
current_ma: int # milliamps (negative = charging)
soc_pct: int # state of charge 0100 (from STM32 fuel gauge or lookup)
class SensorData:
pressure_pa: float = 0.0 # Pascal (barometer)
temperature_c: float = 0.0 # °C
tof_mm: int = 0 # Time-of-flight distance mm
@dataclass
class MotorRpmFrame:
left_rpm: int
right_rpm: int
class LedCmd:
pattern: int = 0
r: int = 0
g: int = 0
b: int = 0
@dataclass
class ArmStateFrame:
state: int # 0=DISARMED 1=ARMED 2=TILT_FAULT
error_flags: int # bitmask
class OutputCmd:
horn: bool = False
buzzer: bool = False
headlight: int = 0 # 0255 PWM
fan: int = 0 # 0255 PWM
@dataclass
class ErrorFrame:
error_code: int
subcode: int
class MotorCmd:
motor_a: int = 0 # -255..+255 (BTS7960 channel A)
motor_b: int = 0 # -255..+255 (BTS7960 channel B)
# Union type for decoded results
TelemetryFrame = ImuFrame | BatteryFrame | MotorRpmFrame | ArmStateFrame | ErrorFrame
@dataclass
class Heartbeat:
state: int = 0 # 0=IDLE 1=RUNNING 2=FAULT
error_flags: int = 0
# ── CRC16 CCITT ───────────────────────────────────────────────────────────────
InterboardMsg = RcChannels | SensorData | LedCmd | OutputCmd | MotorCmd | Heartbeat
def _crc16_ccitt(data: bytes, init: int = 0xFFFF) -> int:
"""CRC16-CCITT: polynomial 0x1021, init 0xFFFF, no final XOR."""
crc = init
# ── CRC-8 (polynomial 0x07, init 0x00) ───────────────────────────────────────
def _crc8(data: bytes) -> int:
crc = 0
for byte in data:
crc ^= byte << 8
crc ^= byte
for _ in range(8):
if crc & 0x8000:
crc = (crc << 1) ^ 0x1021
else:
crc <<= 1
crc &= 0xFFFF
crc = ((crc << 1) ^ 0x07) if (crc & 0x80) else (crc << 1)
crc &= 0xFF
return crc
# ── Frame encoder ─────────────────────────────────────────────────────────────
def _build_frame(cmd_type: int, payload: bytes) -> bytes:
"""Assemble a complete binary frame with CRC16."""
assert len(payload) <= MAX_PAYLOAD_LEN, "Payload too large"
length = len(payload)
header = bytes([cmd_type, length])
crc = _crc16_ccitt(header + payload)
return bytes([STX, cmd_type, length]) + payload + struct.pack(">H", crc) + bytes([ETX])
def _build_frame(msg_type: int, payload: bytes) -> bytes:
assert len(payload) <= MAX_PAYLOAD_LEN
crc_data = bytes([len(payload), msg_type]) + payload
return bytes([FRAME_HEADER, len(payload), msg_type]) + payload + bytes([_crc8(crc_data)])
def encode_heartbeat() -> bytes:
"""HEARTBEAT frame — no payload."""
return _build_frame(CmdType.HEARTBEAT, b"")
def encode_heartbeat(state: int = 0, error_flags: int = 0) -> bytes:
return _build_frame(BalMsg.HEARTBEAT, struct.pack("BB", state & 0xFF, error_flags & 0xFF))
def encode_speed_steer(speed: int, steer: int) -> bytes:
"""SPEED_STEER frame — int16 speed + int16 steer, both in -1000..+1000."""
speed = max(-1000, min(1000, int(speed)))
steer = max(-1000, min(1000, int(steer)))
return _build_frame(CmdType.SPEED_STEER, struct.pack(">hh", speed, steer))
def encode_led_cmd(pattern: int, r: int, g: int, b: int) -> bytes:
return _build_frame(BalMsg.LED_CMD, struct.pack("BBBB", pattern & 0xFF, r & 0xFF, g & 0xFF, b & 0xFF))
def encode_arm(arm: bool) -> bytes:
"""ARM frame — 0=disarm, 1=arm."""
return _build_frame(CmdType.ARM, struct.pack("B", 1 if arm else 0))
def encode_output_cmd(horn: bool, buzzer: bool, headlight: int, fan: int) -> bytes:
flags = (int(horn) & 1) | ((int(buzzer) & 1) << 1)
return _build_frame(BalMsg.OUTPUT_CMD, struct.pack("BBB", flags, headlight & 0xFF, fan & 0xFF))
def encode_set_mode(mode: int) -> bytes:
"""SET_MODE frame — mode byte."""
return _build_frame(CmdType.SET_MODE, struct.pack("B", mode & 0xFF))
def encode_motor_cmd(motor_a: int, motor_b: int) -> bytes:
a = max(-255, min(255, int(motor_a)))
b = max(-255, min(255, int(motor_b)))
return _build_frame(BalMsg.MOTOR_CMD, struct.pack(">hh", a, b))
def encode_pid_update(kp: float, ki: float, kd: float) -> bytes:
"""PID_UPDATE frame — three float32 values."""
return _build_frame(CmdType.PID_UPDATE, struct.pack(">fff", kp, ki, kd))
# ── Streaming frame parser ────────────────────────────────────────────────────
# ── Frame decoder (state-machine parser) ─────────────────────────────────────
class ParserState(IntEnum):
WAIT_STX = 0
WAIT_TYPE = 1
WAIT_LEN = 2
PAYLOAD = 3
CRC_HI = 4
CRC_LO = 5
WAIT_ETX = 6
class ParseError(Exception):
pass
class _St(IntEnum):
HDR = 0
LEN = 1
TYPE = 2
PAY = 3
CRC = 4
class FrameParser:
"""Byte-by-byte streaming parser for STM32 telemetry frames.
Feed individual bytes via feed(); returns a decoded TelemetryFrame (or raw
bytes tuple) when a complete valid frame is received.
Thread-safety: single-threaded wrap in a lock if shared across threads.
"""Byte-by-byte streaming parser for inter-board frames.
Usage::
parser = FrameParser()
for b in incoming:
result = parser.feed(b)
if result is not None:
process(result)
msg = parser.feed(b)
if msg is not None:
handle(msg)
"""
def __init__(self) -> None:
self._state = ParserState.WAIT_STX
def __init__(self):
self._s = _St.HDR
self._len = 0
self._type = 0
self._length = 0
self._payload = bytearray()
self._crc_rcvd = 0
self._pay = bytearray()
self.frames_ok = 0
self.frames_error = 0
def reset(self) -> None:
"""Reset parser to initial state (call after error or port reconnect)."""
self._state = ParserState.WAIT_STX
self._payload = bytearray()
def reset(self):
self._s = _St.HDR
self._pay = bytearray()
def feed(self, byte: int) -> Optional[TelemetryFrame | tuple]:
"""Process one byte. Returns decoded frame on success, None otherwise.
def feed(self, byte: int) -> Optional[InterboardMsg | tuple]:
s = self._s
On CRC error, increments frames_error and resets. The return value on
success is a dataclass (ImuFrame, BatteryFrame, etc.) or a
(type_code, raw_payload) tuple for unknown type codes.
"""
s = self._state
if s == ParserState.WAIT_STX:
if byte == STX:
self._state = ParserState.WAIT_TYPE
if s == _St.HDR:
if byte == FRAME_HEADER:
self._s = _St.LEN
return None
if s == ParserState.WAIT_TYPE:
if s == _St.LEN:
if byte > MAX_PAYLOAD_LEN:
self.frames_error += 1; self.reset(); return None
self._len = byte
self._s = _St.TYPE
return None
if s == _St.TYPE:
self._type = byte
self._state = ParserState.WAIT_LEN
self._pay = bytearray()
self._s = _St.PAY if self._len > 0 else _St.CRC
return None
if s == ParserState.WAIT_LEN:
self._length = byte
self._payload = bytearray()
if self._length > MAX_PAYLOAD_LEN:
# Corrupt frame — too big; reset
self.frames_error += 1
if s == _St.PAY:
self._pay.append(byte)
if len(self._pay) == self._len:
self._s = _St.CRC
return None
if s == _St.CRC:
self.reset()
return None
if self._length == 0:
self._state = ParserState.CRC_HI
else:
self._state = ParserState.PAYLOAD
return None
if s == ParserState.PAYLOAD:
self._payload.append(byte)
if len(self._payload) == self._length:
self._state = ParserState.CRC_HI
return None
if s == ParserState.CRC_HI:
self._crc_rcvd = byte << 8
self._state = ParserState.CRC_LO
return None
if s == ParserState.CRC_LO:
self._crc_rcvd |= byte
self._state = ParserState.WAIT_ETX
return None
if s == ParserState.WAIT_ETX:
self.reset() # always reset so we look for next STX
if byte != ETX:
self.frames_error += 1
return None
# Verify CRC
crc_data = bytes([self._type, self._length]) + self._payload
expected = _crc16_ccitt(crc_data)
if expected != self._crc_rcvd:
self.frames_error += 1
return None
# Decode
expected = _crc8(bytes([self._len, self._type]) + self._pay)
if byte != expected:
self.frames_error += 1; return None
self.frames_ok += 1
return _decode_telemetry(self._type, bytes(self._payload))
return _decode(self._type, bytes(self._pay))
# Should never reach here
self.reset()
return None
self.reset(); return None
# ── Telemetry decoder ─────────────────────────────────────────────────────────
# ── Message decoder ───────────────────────────────────────────────────────────
def _decode_telemetry(type_code: int, payload: bytes) -> Optional[TelemetryFrame | tuple]:
"""Decode a validated telemetry payload into a typed dataclass."""
def _decode(type_code: int, payload: bytes) -> Optional[InterboardMsg | tuple]:
try:
if type_code == TelType.IMU:
if len(payload) < 12:
return None
p, r, y, ax, ay, az = struct.unpack_from(">hhhhhh", payload)
return ImuFrame(
pitch_deg=p / 100.0,
roll_deg=r / 100.0,
yaw_deg=y / 100.0,
accel_x=ax / 100.0,
accel_y=ay / 100.0,
accel_z=az / 100.0,
)
if type_code == IOMsg.RC_CHANNELS:
if len(payload) < 17: return None
ch = list(struct.unpack_from("<8H", payload))
return RcChannels(channels=ch, source=payload[16])
if type_code == TelType.BATTERY:
if len(payload) < 5:
return None
v_mv, i_ma, soc = struct.unpack_from(">HhB", payload)
return BatteryFrame(voltage_mv=v_mv, current_ma=i_ma, soc_pct=soc)
if type_code == IOMsg.SENSORS:
if len(payload) < 10: return None
pres, temp, tof = struct.unpack_from("<ffH", payload)
return SensorData(pressure_pa=pres, temperature_c=temp, tof_mm=tof)
if type_code == TelType.MOTOR_RPM:
if len(payload) < 4:
return None
left, right = struct.unpack_from(">hh", payload)
return MotorRpmFrame(left_rpm=left, right_rpm=right)
if type_code == BalMsg.LED_CMD:
if len(payload) < 4: return None
pat, r, g, b = struct.unpack_from("BBBB", payload)
return LedCmd(pattern=pat, r=r, g=g, b=b)
if type_code == TelType.ARM_STATE:
if len(payload) < 2:
return None
if type_code == BalMsg.OUTPUT_CMD:
if len(payload) < 3: return None
flags, headlight, fan = struct.unpack_from("BBB", payload)
return OutputCmd(horn=bool(flags & 1), buzzer=bool(flags & 2),
headlight=headlight, fan=fan)
if type_code == BalMsg.MOTOR_CMD:
if len(payload) < 4: return None
a, b = struct.unpack_from(">hh", payload)
return MotorCmd(motor_a=a, motor_b=b)
if type_code == BalMsg.HEARTBEAT:
if len(payload) < 2: return None
state, flags = struct.unpack_from("BB", payload)
return ArmStateFrame(state=state, error_flags=flags)
if type_code == TelType.ERROR:
if len(payload) < 2:
return None
code, sub = struct.unpack_from("BB", payload)
return ErrorFrame(error_code=code, subcode=sub)
return Heartbeat(state=state, error_flags=flags)
except struct.error:
return None
# Unknown telemetry type — return raw
return (type_code, payload)

240
jetson/ros2_ws/src/saltybot_can_bridge/saltybot_can_bridge/can_bridge_node.py
View File

@ -1,22 +1,21 @@
#!/usr/bin/env python3
"""
can_bridge_node.py ROS2 node bridging the SaltyBot Orin to the Mamba motor
controller and VESC motor controllers over CAN bus.
can_bridge_node.py ROS2 node bridging the Jetson Orin to the ESP32-S3 BALANCE
board and VESC motor controllers over CAN bus (CANable2 / slcan0, 500 kbps).
The node opens the SocketCAN interface (slcan0 by default), spawns a background
reader thread to process incoming telemetry, and exposes the following interface:
Spec: docs/SAUL-TEE-SYSTEM-REFERENCE.md §4 & §6 (2026-04-04)
Subscriptions
-------------
/cmd_vel geometry_msgs/Twist VESC speed commands (CAN)
/estop std_msgs/Bool Mamba e-stop (CAN)
/cmd_vel geometry_msgs/Twist ORIN_CMD_DRIVE (0x300)
/estop std_msgs/Bool ORIN_CMD_ESTOP (0x302)
Publications
------------
/can/imu sensor_msgs/Imu Mamba IMU telemetry
/can/battery sensor_msgs/BatteryState Mamba battery telemetry
/can/vesc/left/state std_msgs/Float32MultiArray Left VESC state
/can/vesc/right/state std_msgs/Float32MultiArray Right VESC state
/can/imu sensor_msgs/Imu from FC_STATUS (0x400) pitch
/can/battery sensor_msgs/BatteryState from FC_STATUS (0x400) vbat_mv
/can/vesc/left/state std_msgs/Float32MultiArray from FC_VESC (0x401)
/can/vesc/right/state std_msgs/Float32MultiArray from FC_VESC (0x401)
/can/connection_status std_msgs/String "connected" | "disconnected"
Issue: https://gitea.vayrette.com/seb/saltylab-firmware/issues/674
@ -30,30 +29,36 @@ import can
import rclpy
from geometry_msgs.msg import Twist
from rclpy.node import Node
from rcl_interfaces.msg import SetParametersResult
from sensor_msgs.msg import BatteryState, Imu
from std_msgs.msg import Bool, Float32MultiArray, String
from saltybot_can_bridge.mamba_protocol import (
MAMBA_CMD_ESTOP,
MAMBA_CMD_MODE,
MAMBA_CMD_VELOCITY,
MAMBA_TELEM_BATTERY,
MAMBA_TELEM_IMU,
VESC_TELEM_STATE,
ORIN_CAN_ID_FC_PID_ACK,
ORIN_CAN_ID_PID_SET,
# Orin → BALANCE command IDs
ORIN_CMD_DRIVE,
ORIN_CMD_MODE,
ORIN_CMD_ESTOP,
# BALANCE → Orin telemetry IDs
FC_STATUS,
FC_VESC,
# VESC node IDs
VESC_LEFT_ID,
VESC_RIGHT_ID,
VESC_STATUS_1,
# Mode constants
MODE_DRIVE,
MODE_ESTOP,
MODE_IDLE,
encode_estop_cmd,
# Encoders
encode_drive_cmd,
encode_mode_cmd,
encode_velocity_cmd,
encode_pid_set_cmd,
decode_battery_telem,
decode_imu_telem,
decode_pid_ack,
decode_vesc_state,
encode_estop_cmd,
encode_led_cmd,
# Decoders
decode_fc_status,
decode_fc_vesc,
decode_vesc_status1,
decode_vesc_can_id,
)
# Reconnect attempt interval when CAN bus is lost
@ -64,29 +69,21 @@ _WATCHDOG_HZ: float = 10.0
class CanBridgeNode(Node):
"""CAN bus bridge between Orin ROS2 and Mamba / VESC controllers."""
"""CAN bus bridge between Orin ROS2 and ESP32 BALANCE / VESC controllers."""
def __init__(self) -> None:
super().__init__("can_bridge_node")
# ── Parameters ────────────────────────────────────────────────────
self.declare_parameter("can_interface", "slcan0")
self.declare_parameter("left_vesc_can_id", 56)
self.declare_parameter("right_vesc_can_id", 68)
self.declare_parameter("mamba_can_id", 1)
self.declare_parameter("left_vesc_can_id", VESC_LEFT_ID) # 56
self.declare_parameter("right_vesc_can_id", VESC_RIGHT_ID) # 68
self.declare_parameter("command_timeout_s", 0.5)
self.declare_parameter("pid/kp", 0.0)
self.declare_parameter("pid/ki", 0.0)
self.declare_parameter("pid/kd", 0.0)
self._iface: str = self.get_parameter("can_interface").value
self._left_vesc_id: int = self.get_parameter("left_vesc_can_id").value
self._right_vesc_id: int = self.get_parameter("right_vesc_can_id").value
self._mamba_id: int = self.get_parameter("mamba_can_id").value
self._cmd_timeout: float = self.get_parameter("command_timeout_s").value
self._pid_kp: float = self.get_parameter("pid/kp").value
self._pid_ki: float = self.get_parameter("pid/ki").value
self._pid_kd: float = self.get_parameter("pid/kd").value
# ── State ─────────────────────────────────────────────────────────
self._bus: Optional[can.BusABC] = None
@ -110,7 +107,6 @@ class CanBridgeNode(Node):
# ── Subscriptions ─────────────────────────────────────────────────
self.create_subscription(Twist, "/cmd_vel", self._cmd_vel_cb, 10)
self.create_subscription(Bool, "/estop", self._estop_cb, 10)
self.add_on_set_parameters_callback(self._on_set_parameters)
# ── Timers ────────────────────────────────────────────────────────
self.create_timer(1.0 / _WATCHDOG_HZ, self._watchdog_cb)
@ -127,34 +123,9 @@ class CanBridgeNode(Node):
self.get_logger().info(
f"can_bridge_node ready — iface={self._iface} "
f"left_vesc={self._left_vesc_id} right_vesc={self._right_vesc_id} "
f"mamba={self._mamba_id}"
f"left_vesc={self._left_vesc_id} right_vesc={self._right_vesc_id}"
)
# -- PID parameter callback (Issue #693) --
def _on_set_parameters(self, params) -> SetParametersResult:
"""Send new PID gains over CAN when pid/* params change."""
for p in params:
if p.name == "pid/kp":
self._pid_kp = float(p.value)
elif p.name == "pid/ki":
self._pid_ki = float(p.value)
elif p.name == "pid/kd":
self._pid_kd = float(p.value)
else:
continue
try:
payload = encode_pid_set_cmd(self._pid_kp, self._pid_ki, self._pid_kd)
self._send_can(ORIN_CAN_ID_PID_SET, payload, "pid_set")
self.get_logger().info(
f"PID gains sent: Kp={self._pid_kp:.2f} "
f"Ki={self._pid_ki:.2f} Kd={self._pid_kd:.2f}"
)
except ValueError as exc:
return SetParametersResult(successful=False, reason=str(exc))
return SetParametersResult(successful=True)
# ── Connection management ──────────────────────────────────────────────
def _try_connect(self) -> None:
@ -212,29 +183,21 @@ class CanBridgeNode(Node):
linear = msg.linear.x
angular = msg.angular.z
# Forward left = forward right for pure translation; for rotation
# left slows and right speeds up (positive angular = CCW = left turn).
# The Mamba velocity command carries both wheels independently.
# Differential drive decomposition (positive angular = CCW = left turn).
left_mps = linear - angular
right_mps = linear + angular
payload = encode_velocity_cmd(left_mps, right_mps)
self._send_can(MAMBA_CMD_VELOCITY, payload, "cmd_vel")
# Keep Mamba in DRIVE mode while receiving commands
self._send_can(MAMBA_CMD_MODE, encode_mode_cmd(MODE_DRIVE), "cmd_vel mode")
self._send_can(ORIN_CMD_DRIVE, encode_drive_cmd(left_mps, right_mps), "cmd_vel")
self._send_can(ORIN_CMD_MODE, encode_mode_cmd(MODE_DRIVE), "cmd_vel mode")
def _estop_cb(self, msg: Bool) -> None:
"""Forward /estop to Mamba over CAN."""
"""Forward /estop to ESP32 BALANCE over CAN."""
if not self._connected:
return
payload = encode_estop_cmd(msg.data)
self._send_can(MAMBA_CMD_ESTOP, payload, "estop")
self._send_can(ORIN_CMD_ESTOP, encode_estop_cmd(stop=msg.data), "estop")
if msg.data:
self._send_can(
MAMBA_CMD_MODE, encode_mode_cmd(MODE_ESTOP), "estop mode"
)
self.get_logger().warning("E-stop asserted — sent ESTOP to Mamba")
self._send_can(ORIN_CMD_MODE, encode_mode_cmd(MODE_ESTOP), "estop mode")
self.get_logger().warning("E-stop asserted — sent ESTOP to ESP32 BALANCE")
# ── Watchdog ──────────────────────────────────────────────────────────
@ -244,14 +207,8 @@ class CanBridgeNode(Node):
return
elapsed = time.monotonic() - self._last_cmd_time
if elapsed > self._cmd_timeout:
self._send_can(
MAMBA_CMD_VELOCITY,
encode_velocity_cmd(0.0, 0.0),
"watchdog zero-vel",
)
self._send_can(
MAMBA_CMD_MODE, encode_mode_cmd(MODE_IDLE), "watchdog idle"
)
self._send_can(ORIN_CMD_DRIVE, encode_drive_cmd(0.0, 0.0), "watchdog zero-vel")
self._send_can(ORIN_CMD_MODE, encode_mode_cmd(MODE_IDLE), "watchdog idle")
# ── CAN send helper ───────────────────────────────────────────────────
@ -305,24 +262,28 @@ class CanBridgeNode(Node):
arb_id = frame.arbitration_id
data = bytes(frame.data)
# VESC STATUS_1 CAN IDs: (VESC_STATUS_1 << 8) | node_id
_vesc_left_status1 = (VESC_STATUS_1 << 8) | self._left_vesc_id
_vesc_right_status1 = (VESC_STATUS_1 << 8) | self._right_vesc_id
try:
if arb_id == MAMBA_TELEM_IMU:
self._handle_imu(data, frame.timestamp)
if arb_id == FC_STATUS:
self._handle_fc_status(data)
elif arb_id == MAMBA_TELEM_BATTERY:
self._handle_battery(data, frame.timestamp)
elif arb_id == FC_VESC:
self._handle_fc_vesc(data)
elif arb_id == VESC_TELEM_STATE + self._left_vesc_id:
self._handle_vesc_state(data, frame.timestamp, side="left")
elif arb_id == _vesc_left_status1:
telem = decode_vesc_status1(self._left_vesc_id, data)
msg = Float32MultiArray()
msg.data = [telem.erpm, telem.duty, 0.0, telem.current]
self._pub_vesc_left.publish(msg)
elif arb_id == VESC_TELEM_STATE + self._right_vesc_id:
self._handle_vesc_state(data, frame.timestamp, side="right")
elif arb_id == ORIN_CAN_ID_FC_PID_ACK:
gains = decode_pid_ack(data)
self.get_logger().debug(
f"FC PID ACK: Kp={gains.kp:.2f} Ki={gains.ki:.2f} Kd={gains.kd:.2f}"
)
elif arb_id == _vesc_right_status1:
telem = decode_vesc_status1(self._right_vesc_id, data)
msg = Float32MultiArray()
msg.data = [telem.erpm, telem.duty, 0.0, telem.current]
self._pub_vesc_right.publish(msg)
except Exception as exc:
self.get_logger().warning(
@ -331,51 +292,38 @@ class CanBridgeNode(Node):
# ── Frame handlers ────────────────────────────────────────────────────
def _handle_imu(self, data: bytes, timestamp: float) -> None:
telem = decode_imu_telem(data)
def _handle_fc_status(self, data: bytes) -> None:
"""FC_STATUS (0x400): pitch, motor_cmd, vbat_mv, state, flags."""
telem = decode_fc_status(data)
msg = Imu()
msg.header.stamp = self.get_clock().now().to_msg()
msg.header.frame_id = "imu_link"
# Publish pitch as IMU (orientation only — yaw/roll unknown from FC_STATUS)
imu_msg = Imu()
imu_msg.header.stamp = self.get_clock().now().to_msg()
imu_msg.header.frame_id = "imu_link"
# Only pitch is available; publish as angular velocity placeholder
imu_msg.angular_velocity.y = telem.pitch_deg # degrees, not rad/s
imu_msg.orientation_covariance[0] = -1.0 # covariance unknown
self._pub_imu.publish(imu_msg)
msg.linear_acceleration.x = telem.accel_x
msg.linear_acceleration.y = telem.accel_y
msg.linear_acceleration.z = telem.accel_z
# Publish battery (vbat_mv → volts)
bat_msg = BatteryState()
bat_msg.header.stamp = imu_msg.header.stamp
bat_msg.voltage = telem.vbat_mv / 1000.0
bat_msg.present = True
bat_msg.power_supply_status = BatteryState.POWER_SUPPLY_STATUS_DISCHARGING
self._pub_battery.publish(bat_msg)
msg.angular_velocity.x = telem.gyro_x
msg.angular_velocity.y = telem.gyro_y
msg.angular_velocity.z = telem.gyro_z
def _handle_fc_vesc(self, data: bytes) -> None:
"""FC_VESC (0x401): left/right RPM and current aggregated by BALANCE."""
telem = decode_fc_vesc(data)
# Covariance unknown; mark as -1 per REP-145
msg.orientation_covariance[0] = -1.0
left_msg = Float32MultiArray()
left_msg.data = [telem.left_rpm, 0.0, 0.0, telem.left_cur]
self._pub_vesc_left.publish(left_msg)
self._pub_imu.publish(msg)
def _handle_battery(self, data: bytes, timestamp: float) -> None:
telem = decode_battery_telem(data)
msg = BatteryState()
msg.header.stamp = self.get_clock().now().to_msg()
msg.voltage = telem.voltage
msg.current = telem.current
msg.present = True
msg.power_supply_status = BatteryState.POWER_SUPPLY_STATUS_DISCHARGING
self._pub_battery.publish(msg)
def _handle_vesc_state(
self, data: bytes, timestamp: float, side: str
) -> None:
telem = decode_vesc_state(data)
msg = Float32MultiArray()
# Layout: [erpm, duty, voltage, current]
msg.data = [telem.erpm, telem.duty, telem.voltage, telem.current]
if side == "left":
self._pub_vesc_left.publish(msg)
else:
self._pub_vesc_right.publish(msg)
right_msg = Float32MultiArray()
right_msg.data = [telem.right_rpm, 0.0, 0.0, telem.right_cur]
self._pub_vesc_right.publish(right_msg)
# ── Status helper ─────────────────────────────────────────────────────
@ -390,14 +338,8 @@ class CanBridgeNode(Node):
"""Send zero velocity and shut down the CAN bus cleanly."""
if self._connected and self._bus is not None:
try:
self._send_can(
MAMBA_CMD_VELOCITY,
encode_velocity_cmd(0.0, 0.0),
"shutdown",
)
self._send_can(
MAMBA_CMD_MODE, encode_mode_cmd(MODE_IDLE), "shutdown"
)
self._send_can(ORIN_CMD_DRIVE, encode_drive_cmd(0.0, 0.0), "shutdown")
self._send_can(ORIN_CMD_MODE, encode_mode_cmd(MODE_IDLE), "shutdown")
except Exception:
pass
try:

311
jetson/ros2_ws/src/saltybot_can_bridge/saltybot_can_bridge/mamba_protocol.py
View File

@ -1,87 +1,115 @@
#!/usr/bin/env python3
"""
mamba_protocol.py CAN message encoding/decoding for the Mamba motor controller
and VESC telemetry.
"""mamba_protocol.py — CAN frame codec for SAUL-TEE ESP32 BALANCE + VESC.
CAN message layout
------------------
Command frames (Orin Mamba / VESC):
MAMBA_CMD_VELOCITY 0x100 8 bytes left_speed (f32, m/s) | right_speed (f32, m/s)
MAMBA_CMD_MODE 0x101 1 byte mode (0=idle, 1=drive, 2=estop)
MAMBA_CMD_ESTOP 0x102 1 byte 0x01 = stop
Spec source: docs/SAUL-TEE-SYSTEM-REFERENCE.md §6 & §8 (2026-04-04)
Telemetry frames (Mamba Orin):
MAMBA_TELEM_IMU 0x200 24 bytes accel_x, accel_y, accel_z, gyro_x, gyro_y, gyro_z (f32 each)
MAMBA_TELEM_BATTERY 0x201 8 bytes voltage (f32, V) | current (f32, A)
File name retained for import compatibility.
VESC telemetry frame (VESC Orin):
VESC_TELEM_STATE 0x300 16 bytes erpm (f32) | duty (f32) | voltage (f32) | current (f32)
CAN bus: 500 kbps, CANable 2.0 (slcan0) on Orin.
All multi-byte fields are big-endian.
Orin ESP32 BALANCE (commands)
0x300 DRIVE 8 B [left_mps f32 LE][right_mps f32 LE] velocity setpoint
0x301 MODE 1 B [mode u8] 0=idle 1=drive 2=estop
0x302 ESTOP 1 B [flags u8] bit0=stop bit1=clear
0x303 LED 4 B [pattern u8][r u8][g u8][b u8]
Issue: https://gitea.vayrette.com/seb/saltylab-firmware/issues/674
ESP32 BALANCE Orin (telemetry)
0x400 FC_STATUS 8 B [pitch_x10 i16][motor_cmd i16][vbat_mv u16][state u8][flags u8] 10 Hz
0x401 FC_VESC 8 B [l_rpm_x10 i16][r_rpm_x10 i16][l_cur_x10 i16][r_cur_x10 i16] 10 Hz
VESC standard CAN frames (29-bit extended IDs)
VESC node IDs: Left = 56, Right = 68
ID = (packet_type << 8) | node_id
SET_RPM cmd=3 payload: rpm i32 big-endian
STATUS cmd=9 payload: erpm i32, current i16, duty i16
STATUS_4 cmd=16 payload: temp_fet×10 i16, temp_motor×10 i16,
current_in×10 i16, pid_pos×50 i16
STATUS_5 cmd=27 payload: tacho i32, vbat×10 i16
"""
import struct
from dataclasses import dataclass
from typing import Tuple
# ---------------------------------------------------------------------------
# CAN message IDs
# ---------------------------------------------------------------------------
# ── CAN IDs ───────────────────────────────────────────────────────────────────
MAMBA_CMD_VELOCITY: int = 0x100
MAMBA_CMD_MODE: int = 0x101
MAMBA_CMD_ESTOP: int = 0x102
# Orin → ESP32 BALANCE
ORIN_CMD_DRIVE: int = 0x300
ORIN_CMD_MODE: int = 0x301
ORIN_CMD_ESTOP: int = 0x302
ORIN_CMD_LED: int = 0x303
MAMBA_TELEM_IMU: int = 0x200
MAMBA_TELEM_BATTERY: int = 0x201
# ESP32 BALANCE → Orin
FC_STATUS: int = 0x400
FC_VESC: int = 0x401
VESC_TELEM_STATE: int = 0x300
ORIN_CAN_ID_PID_SET: int = 0x305
ORIN_CAN_ID_FC_PID_ACK: int = 0x405
# VESC node IDs (per docs/SAUL-TEE-SYSTEM-REFERENCE.md §8)
VESC_LEFT_ID: int = 56
VESC_RIGHT_ID: int = 68
# ---------------------------------------------------------------------------
# Mode constants
# ---------------------------------------------------------------------------
# VESC CAN packet types (standard VESC protocol)
VESC_CMD_SET_RPM: int = 3
VESC_STATUS_1: int = 9
VESC_STATUS_4: int = 16
VESC_STATUS_5: int = 27
# ── Mode constants ────────────────────────────────────────────────────────────
MODE_IDLE: int = 0
MODE_DRIVE: int = 1
MODE_ESTOP: int = 2
# ---------------------------------------------------------------------------
# Data classes for decoded telemetry
# ---------------------------------------------------------------------------
# ── Data classes ──────────────────────────────────────────────────────────────
@dataclass
class DriveCmd:
left_mps: float = 0.0 # m/s, positive = forward
right_mps: float = 0.0
@dataclass
class ImuTelemetry:
"""Decoded IMU telemetry from Mamba (MAMBA_TELEM_IMU)."""
accel_x: float = 0.0 # m/s²
accel_y: float = 0.0
accel_z: float = 0.0
gyro_x: float = 0.0 # rad/s
gyro_y: float = 0.0
gyro_z: float = 0.0
class FcStatus:
"""Decoded FC_STATUS (0x400) telemetry from ESP32 BALANCE."""
pitch_deg: float = 0.0 # pitch_x10 / 10.0
motor_cmd: int = 0 # raw motor command output
vbat_mv: int = 0 # battery voltage in mV
state: int = 0 # 0=idle 1=running 2=fault
flags: int = 0 # error bitmask
@dataclass
class BatteryTelemetry:
"""Decoded battery telemetry from Mamba (MAMBA_TELEM_BATTERY)."""
class FcVesc:
"""Decoded FC_VESC (0x401) VESC aggregate telemetry."""
left_rpm: float = 0.0 # left_rpm_x10 / 10.0
right_rpm: float = 0.0
left_cur: float = 0.0 # left_cur_x10 / 10.0 (amps)
right_cur: float = 0.0
voltage: float = 0.0 # V
@dataclass
class VescStatus1:
"""Decoded VESC STATUS (cmd=9) frame."""
node_id: int = 0
erpm: float = 0.0
current: float = 0.0 # A
duty: float = 0.0 # -1.0..+1.0
@dataclass
class VescStateTelemetry:
"""Decoded VESC state telemetry (VESC_TELEM_STATE)."""
class VescStatus4:
"""Decoded VESC STATUS_4 (cmd=16) frame."""
node_id: int = 0
temp_fet_c: float = 0.0
temp_motor_c: float = 0.0
current_in: float = 0.0
erpm: float = 0.0 # electrical RPM
duty: float = 0.0 # duty cycle [-1.0, 1.0]
voltage: float = 0.0 # bus voltage, V
current: float = 0.0 # phase current, A
@dataclass
class VescStatus5:
"""Decoded VESC STATUS_5 (cmd=27) frame."""
node_id: int = 0
tacho: int = 0
vbat_v: float = 0.0
@dataclass
@ -92,133 +120,98 @@ class PidGains:
kd: float = 0.0
# ---------------------------------------------------------------------------
# Encode helpers
# ---------------------------------------------------------------------------
# ── Orin → BALANCE encoders ───────────────────────────────────────────────────
_FMT_VEL = ">ff" # 2 × float32, big-endian
_FMT_MODE = ">B" # 1 × uint8
_FMT_ESTOP = ">B" # 1 × uint8
_FMT_IMU = ">ffffff" # 6 × float32
_FMT_BAT = ">ff" # 2 × float32
_FMT_VESC = ">ffff" # 4 × float32
def encode_velocity_cmd(left_mps: float, right_mps: float) -> bytes:
"""
Encode a MAMBA_CMD_VELOCITY payload.
Parameters
----------
left_mps: target left wheel speed in m/s (positive = forward)
right_mps: target right wheel speed in m/s (positive = forward)
Returns
-------
8-byte big-endian payload suitable for a CAN frame.
"""
return struct.pack(_FMT_VEL, float(left_mps), float(right_mps))
def encode_drive_cmd(left_mps: float, right_mps: float) -> bytes:
"""Encode ORIN_CMD_DRIVE (0x300) — 8 bytes, float32 LE."""
return struct.pack("<ff", float(left_mps), float(right_mps))
def encode_mode_cmd(mode: int) -> bytes:
"""
Encode a MAMBA_CMD_MODE payload.
Parameters
----------
mode: one of MODE_IDLE (0), MODE_DRIVE (1), MODE_ESTOP (2)
Returns
-------
1-byte payload.
"""
"""Encode ORIN_CMD_MODE (0x301) — 1 byte."""
if mode not in (MODE_IDLE, MODE_DRIVE, MODE_ESTOP):
raise ValueError(f"Invalid mode {mode!r}; expected 0, 1, or 2")
return struct.pack(_FMT_MODE, mode)
raise ValueError(f"Invalid mode {mode!r}")
return struct.pack("B", mode)
def encode_estop_cmd(stop: bool = True) -> bytes:
"""
Encode a MAMBA_CMD_ESTOP payload.
Parameters
----------
stop: True to assert e-stop, False to clear.
Returns
-------
1-byte payload (0x01 = stop, 0x00 = clear).
"""
return struct.pack(_FMT_ESTOP, 0x01 if stop else 0x00)
def encode_estop_cmd(stop: bool = True, clear: bool = False) -> bytes:
"""Encode ORIN_CMD_ESTOP (0x302) — 1 byte flags (bit0=stop, bit1=clear)."""
flags = (0x01 if stop else 0) | (0x02 if clear else 0)
return struct.pack("B", flags)
def encode_pid_set_cmd(kp: float, ki: float, kd: float) -> bytes:
"""Encode ORIN_CAN_ID_PID_SET (6 bytes, uint16 BE x3). Issue #693."""
if kp < 0.0 or ki < 0.0 or kd < 0.0:
raise ValueError("PID gains must be non-negative")
return struct.pack(_FMT_PID, round(min(kp,_PID_KP_MAX)*100), round(min(ki,_PID_KI_MAX)*100), round(min(kd,_PID_KD_MAX)*100))
def encode_led_cmd(pattern: int, r: int, g: int, b: int) -> bytes:
"""Encode ORIN_CMD_LED (0x303) — 4 bytes."""
return struct.pack("BBBB", pattern & 0xFF, r & 0xFF, g & 0xFF, b & 0xFF)
# ---------------------------------------------------------------------------
# Decode helpers
# ---------------------------------------------------------------------------
# ── VESC encoders ─────────────────────────────────────────────────────────────
def decode_imu_telem(data: bytes) -> ImuTelemetry:
"""
Decode a MAMBA_TELEM_IMU payload.
def encode_vesc_set_rpm(node_id: int, rpm: int) -> tuple[int, bytes]:
"""Encode VESC SET_RPM command. Returns (can_id, payload)."""
can_id = (VESC_CMD_SET_RPM << 8) | (node_id & 0xFF)
return can_id, struct.pack(">i", int(rpm))
Parameters
----------
data: exactly 24 bytes (6 × float32, big-endian).
Returns
-------
ImuTelemetry dataclass instance.
# ── BALANCE → Orin decoders ───────────────────────────────────────────────────
Raises
------
struct.error if data is the wrong length.
"""
ax, ay, az, gx, gy, gz = struct.unpack(_FMT_IMU, data)
return ImuTelemetry(
accel_x=ax, accel_y=ay, accel_z=az,
gyro_x=gx, gyro_y=gy, gyro_z=gz,
def decode_fc_status(data: bytes) -> FcStatus:
"""Decode FC_STATUS (0x400) — 8 bytes."""
if len(data) < 8:
raise ValueError(f"FC_STATUS expects 8 bytes, got {len(data)}")
pitch_x10, motor_cmd, vbat_mv, state, flags = struct.unpack_from(">hHHBB", data)
return FcStatus(
pitch_deg=pitch_x10 / 10.0,
motor_cmd=motor_cmd,
vbat_mv=vbat_mv,
state=state,
flags=flags,
)
def decode_battery_telem(data: bytes) -> BatteryTelemetry:
"""
Decode a MAMBA_TELEM_BATTERY payload.
Parameters
----------
data: exactly 8 bytes (2 × float32, big-endian).
Returns
-------
BatteryTelemetry dataclass instance.
"""
voltage, current = struct.unpack(_FMT_BAT, data)
return BatteryTelemetry(voltage=voltage, current=current)
def decode_fc_vesc(data: bytes) -> FcVesc:
"""Decode FC_VESC (0x401) — 8 bytes."""
if len(data) < 8:
raise ValueError(f"FC_VESC expects 8 bytes, got {len(data)}")
l_rpm, r_rpm, l_cur, r_cur = struct.unpack_from(">hhhh", data)
return FcVesc(
left_rpm=l_rpm / 10.0,
right_rpm=r_rpm / 10.0,
left_cur=l_cur / 10.0,
right_cur=r_cur / 10.0,
)
def decode_vesc_state(data: bytes) -> VescStateTelemetry:
"""
Decode a VESC_TELEM_STATE payload.
# ── VESC telemetry decoders ───────────────────────────────────────────────────
Parameters
----------
data: exactly 16 bytes (4 × float32, big-endian).
Returns
-------
VescStateTelemetry dataclass instance.
"""
erpm, duty, voltage, current = struct.unpack(_FMT_VESC, data)
return VescStateTelemetry(erpm=erpm, duty=duty, voltage=voltage, current=current)
def decode_vesc_can_id(can_id: int) -> tuple[int, int]:
"""Split a VESC extended CAN ID into (packet_type, node_id)."""
return (can_id >> 8) & 0xFF, can_id & 0xFF
def decode_pid_ack(data: bytes) -> PidGains:
"""Decode ORIN_CAN_ID_FC_PID_ACK (6 bytes). Issue #693."""
kp_x100, ki_x100, kd_x100 = struct.unpack(_FMT_PID, data)
return PidGains(kp=kp_x100/100.0, ki=ki_x100/100.0, kd=kd_x100/100.0)
def decode_vesc_status1(node_id: int, data: bytes) -> VescStatus1:
"""Decode VESC STATUS (cmd=9) — erpm i32, current i16, duty i16."""
erpm, cur_x10, duty_x1000 = struct.unpack_from(">ihh", data[:8])
return VescStatus1(
node_id=node_id,
erpm=float(erpm),
current=cur_x10 / 10.0,
duty=duty_x1000 / 1000.0,
)
def decode_vesc_status4(node_id: int, data: bytes) -> VescStatus4:
"""Decode VESC STATUS_4 (cmd=16) — temp_fet×10, temp_motor×10, current_in×10."""
tfet, tmot, cur_in, _ = struct.unpack_from(">hhhh", data[:8])
return VescStatus4(
node_id=node_id,
temp_fet_c=tfet / 10.0,
temp_motor_c=tmot / 10.0,
current_in=cur_in / 10.0,
)
def decode_vesc_status5(node_id: int, data: bytes) -> VescStatus5:
"""Decode VESC STATUS_5 (cmd=27) — tacho i32, vbat×10 i16."""
tacho, vbat_x10 = struct.unpack_from(">ih", data[:6])
return VescStatus5(node_id=node_id, tacho=tacho, vbat_v=vbat_x10 / 10.0)