robot_MCP

robot_MCP

3.4

If you are the rightful owner of robot_MCP and would like to certify it and/or have it hosted online, please leave a comment on the right or send an email to henry@mcphub.com.

The Model Context Protocol (MCP) server is designed to facilitate the control of robots using LLM-based AI agents, providing both manual and automated control options.

SO-ARM100 Robot Control with MCP

A companion repository to my video about MCP server for the robot:

  • MCP Server for LLM-based AI agents (Claude Desktop, Cursor, Windsurf, etc.) to control the robot
  • Direct keyboard control for manual operation
  • CLI AI Agent can use it directly to control the robot with Claude, Gemini or GPT model

If you want to know more about MCP refer to the official MCP documentation

This repository suppose to work with the SO-ARM100 / 101 robots. Refer to lerobot SO-101 setup guide for the detailed instructions on how to setup the robot.

Update! Now it partially supports LeKiwi (only arm, the mobile base control through MCP is TBD). I also added a simple agent that uses MCP server to control the robot. It supports Claude, Gemini and GPT models. In my experience Claude is the best and GPT is not so good, Gemini is in between.

After I released the video and this repository, LeRobot released a significant update of the library that breaks the compatibility with the original code.

If you want to use the original code and exactly follow the video, please use this release.

Quick Start

1. Install Dependencies

For simplicity I use simple pip instead of uv that is often recommended in MCP tutorials - it works just fine.

python -m venv .venv
source .venv/bin/activate  # or .venv\Scripts\activate on Windows
pip install -r requirements.txt

It may be required to install lerobot separately, just use the official instructions from the lerobot repository

2. Connect Your Robot

  • Connect SO-ARM100 via USB
  • Update config.py with your serial port for so-arm (e.g., /dev/tty.usbmodem58FD0168731) or robot_ip for lekiwi (e.g., 192.168.1.1)
  • Connect cameras and update config.py with the correct indices and names (for lekiwi only names are important)

3. Use the robot

🔍 Check Robot Status and Calibration:

python check_positions.py

This will show you the current robot state without actual control. Move your robot manually to make sure it is properly calibrated and configured.

After the latest update, lerobot is using the normalized joints states instead of degrees. You can update MOTOR_NORMALIZED_TO_DEGREE_MAPPING in config.py to match your robot calibration. You will need to update these values every time you recalibrate the robot.

🎮 Manual Keyboard Control:

python keyboard_controller.py

Now you can try to control the robot manually using the keyboard. Test it before moving on to the MCP step, to make sure it works properly.

🛠️ MCP server in the dev mode

mcp dev mcp_robot_server.py

Final test step - to debug the MCP server, use the UI to connect to it and try to send some requests.

🤖 AI Agent Control (MCP Server):

WARNING: using MCP server itself is free, but it requires MCP client that will send requests to some LLM. Generally it is not free - and controlling the robot with MCP can become expensive, as it sends multiple agentic requests with images that use a lot of tokens. Make sure you understand and control your token usage and corresponding costs before doing it. The actual cost depends on the client and models you use, and it is your responsibility to monitor and control it.

mcp run mcp_robot_server.py --transport SELECTED_TRANSPORT

Supports: stdio, sse, streamable-http

Now your server can be added to any MCP client.

Connecting MCP Clients

Different clients can support different transports, you can choose the one that works best for you. The functionality is the same.

STDIO transport

Add to your MCP configuration:

{
  "mcpServers": {
    "SO-ARM100 robot controller": {
      "command": "/path/to/.venv/bin/python",
      "args": ["/path/to/mcp_robot_server.py"]
    }
  }
}

SEE transport

Run the server in terminal with the SSE transport:

mcp run mcp_robot_server.py --transport sse

Add to your MCP configuration:

{
  "mcpServers": {
    "SO-ARM100 robot controller": {
      "url": "http://127.0.0.1:3001/sse"
    }
  }
}

Streamed-HTTP transport

It is suppose to be a replacement for SSE but currently not so many clients support it.

Run the server in terminal with the Streamed-HTTP transport:

mcp run mcp_robot_server.py --transport streamable-http

Add to your MCP configuration:

{
  "mcpServers": {
    "SO-ARM100 robot controller": {
      "url": "http://127.0.0.1:3001/mcp"
    }
  }
}

Using the robot with MCP

Now you can go to you Client and it should be able to control the robot when you give it the natural language instructions.

Using the Agent

Start the MCP server with the SSE transport:

mcp run mcp_robot_server.py --transport sse

Now you can use the AI agent to control the robot with natural language instructions.

Configuration

Create a .env file in the project root with your API keys:

# API Keys (at least one required)
ANTHROPIC_API_KEY=your_anthropic_api_key_here
GEMINI_API_KEY=your_gemini_api_key_here
OPENAI_API_KEY=your_openai_api_key_here

# MCP Server Configuration (optional)
MCP_SERVER_IP=127.0.0.1
MCP_PORT=3001

Basic Usage

python agent.py

Advanced Usage

# Use Gemini instead of Claude
python agent.py --model gemini-2.5-flash

# Override API key
python agent.py --api-key your_api_key_here

# Enable image viewer window
python agent.py --show-images

# Increase thinking budget for better reasoning
python agent.py --thinking-budget 2048

# Custom MCP server location
python agent.py --mcp-server-ip 192.168.1.100 --mcp-port 3002

Supported Models (examples)

Claude (Anthropic):

  • claude-3-7-sonnet-latest (default)
  • All models support thinking, streaming, and multimodal tool results

Gemini (Google):

  • gemini-2.5-flash
  • gemini-2.5-pro
  • Use 2.5+ models as they support thinking feature

GPT (OpenAI):

  • gpt-4o and variants
  • The rest of the models mostly don't support thinking or tool calling.

Overall I didn't manage to get good results with GPT models.

Parameters

  • --model: LLM model to use (default: claude-3-7-sonnet-latest)
  • --api-key: API key override (uses .env file by default)
  • --show-images: Display robot camera images in a window
  • --thinking-budget: Thinking tokens budget (default: 1024, 0 to disable)
  • --thinking-every-n: Use thinking every N steps (default: 3)
  • --mcp-server-ip: MCP server IP address (default: 127.0.0.1)
  • --mcp-port: MCP server port (default: 3001)

Cost Considerations

Token Usage:

  • Claude counts MCP images in input tokens (more expensive for vision tasks)
  • Gemini doesn't count MCP images in tokens (token usage will be displayed only for text)
  • Thinking tokens add to the cost but improve reasoning quality