• Stars
    star
    540
  • Rank 82,257 (Top 2 %)
  • Language
    Python
  • License
    Other
  • Created almost 2 years ago
  • Updated 5 months ago

Reviews

There are no reviews yet. Be the first to send feedback to the community and the maintainers!

Repository Details

Sim-to-real RL training and deployment tools for the Unitree Go1 robot.

Go1 Sim-to-Real Locomotion Starter Kit

Table of contents

  1. Overview
  2. System Requirements
  3. Training a Model
    1. Installation
    2. Environment and Model Configuration
    3. Training and Logging
    4. Analyzing the Policy
  4. Deploying a Model
    1. Installing the Deployment Utility
    2. Running the Controller
    3. RC Configuration
    4. Deploying a Custom Model
    5. Deployment and Logging
    6. Analyzing Real-world Performance
  5. Debugging Common Errors

Overview

This repository provides an implementation of the paper:

Walk these Ways: Tuning Robot Control for Generalization with Multiplicity of Behavior
Gabriel B. Margolis and Pulkit Agrawal
Conference on Robot Learning, 2022
paper / project page

If you use this repository in your work, consider citing:

@article{margolis2022walktheseways,
    title={Walk These Ways: Tuning Robot Control for Generalization with Multiplicity of Behavior},
    author={Margolis, Gabriel B and Agrawal, Pulkit},
    journal={Conference on Robot Learning},
    year={2022}
}

This environment builds on the legged gym environment by Nikita Rudin, Robotic Systems Lab, ETH Zurich (Paper: https://arxiv.org/abs/2109.11978) and the Isaac Gym simulator from NVIDIA (Paper: https://arxiv.org/abs/2108.10470). Training code builds on the rsl_rl repository, also by Nikita Rudin, Robotic Systems Lab, ETH Zurich. All redistributed code retains its original license.

Our initial release provides the following features:

  • Train reinforcement learning policies for the Go1 robot using PPO, IsaacGym, Domain Randomization, and Multiplicity of Behavior (MoB).
  • Evaluate a pretrained MoB policy in simulation.
  • Deploy learned policies on the Go1 using the unitree_legged_sdk.

System Requirements

Simulated Training and Evaluation: Isaac Gym requires an NVIDIA GPU. To train in the default configuration, we recommend a GPU with at least 10GB of VRAM. The code can run on a smaller GPU if you decrease the number of parallel environments (Cfg.env.num_envs). However, training will be slower with fewer environments.

Hardware Deployment: We provide deployment code for the Unitree Go1 Edu robot. This relatively low-cost, commercially available quadruped can be purchased here: https://shop.unitree.com/. You will need the Edu version of the robot to run and customize your locomotion controller.

Training a Model

Installation

Install pytorch 1.10 with cuda-11.3:

pip3 install torch==1.10.0+cu113 torchvision==0.11.1+cu113 torchaudio==0.10.0+cu113 -f https://download.pytorch.org/whl/cu113/torch_stable.html

Install Isaac Gym

  1. Download and install Isaac Gym Preview 4 from https://developer.nvidia.com/isaac-gym

  2. unzip the file via:

    tar -xf IsaacGym_Preview_4_Package.tar.gz
  3. now install the python package

    cd isaacgym/python && pip install -e .
  4. Verify the installation by try running an example

    python examples/1080_balls_of_solitude.py
  5. For troubleshooting check docs isaacgym/docs/index.html

Install the go1_gym package

In this repository, run pip install -e .

Verifying the Installation

If everything is installed correctly, you should be able to run the test script with:

python scripts/test.py

The script should print Simulating step {i}. The GUI is off by default. To turn it on, set headless=False in test.py's main function call.

Environment and Model Configuration

CODE STRUCTURE The main environment for simulating a legged robot is in legged_robot.py. The default configuration parameters including reward weightings are defined in legged_robot_config.py::Cfg.

There are three scripts in the scripts directory:

scripts
├── __init__.py
├── play.py
├── test.py
└── train.py

You can run the test.py script to verify your environment setup. If it runs then you have installed the gym environments correctly. To train an agent, run train.py. To evaluate a pretrained agent, run play.py. We provie a pretrained agent checkpoint in the ./runs/pretrain-v0 directory.

Training and Logging

To train the Go1 controller from Walk these Ways, run:

python scripts/train.py

After initializing the simulator, the script will print out a list of metrics every ten training iterations.

Training with the default configuration requires about 12GB of GPU memory. If you have less memory available, you can still train by reducing the number of parallel environments used in simulation (the default is Cfg.env.num_envs = 4000).

To visualize training progress, first start the ml_dash frontend app:

python -m ml_dash.app

then start the ml_dash backend server by running this command in the parent directory of the runs folder:

python -m ml_dash.server .

Finally, use a web browser to go to the app IP (defaults to localhost:3001) and create a new profile with the credentials:

Username: runs API: [server IP] (defaults to localhost:8081) Access Token: [blank]

Now, clicking on the profile should yield a dashboard interface visualizing the training runs.

Analyzing the Policy

To evaluate the most recently trained model, run:

python scripts/play.py

The robot is commanded to run forward at 3m/s for 5 seconds. After completing the simulation, the script plots the robot's velocity and joint angles.

The GUI is on by default. If it does not appear, and you're working in docker, make sure you haven't forgotten to run bash docker/visualize_access.bash.

Deploying a Model

Safety Recommendations

Users are advised to follow Unitree's recommendations for safety while using the Go1 in low-level control mode.

  • This means hanging up the robot and keeping it away from people and obstacles.
  • In practice, the main safety consideration we've found important has been not plug anything into the robot's back (ethernet cable, USB) during the initial calibration or when testing a new policy because it can hurt the robot in case of a fall.
  • Our code implements the safety layer from Unitree's unitree_legged_sdk with PowerProtect level 9. This will cut off power to the motors if the joint torque is too high (could happen sometimes during fast running)
  • This is research code; use at your own risk; we do not take responsibility for any damage.

Installing the Deployment Utility

The first step is to connect your development machine to the robot using ethernet. You should ping the robot to verify the connection: ping 192.168.123.15 should return x packets transmitted, x received, 0% packet loss.

Once you have confirmed the robot is connected, run the following command on your computer to transfer files to the robot. The first time you run it, the script will download and transfer the zipped docker image for development on the robot (deployment_image.tar). This file is quite large (3.5GB), but it only needs to be downloaded and transferred once.

cd go1_gym_deploy/scripts && ./send_to_unitree.sh

Next, you will log onto the robot's onboard computer and install the docker environment. To enter the onboard computer, the command is:

Now, run the following commands on the robot's onboard computer:

chmod +x installer/install_deployment_code.sh
cd ~/go1_gym/go1_gym_deploy/scripts
sudo ../installer/install_deployment_code.sh

The installer will automatically unzip and install the docker image containing the deployment environment.

Running the Controller

Place the robot into damping mode. The control sequence is: [L2+A], [L2+B], [L1+L2+START]. After this, the robot should sit on the ground and the joints should move freely.

Now, ssh to [email protected] and run the following two commands to start the controller. This will operate the robot in low-level control mode. Make sure your Go1 is hung up.

First:

cd ~/go1_gym/go1_gym_deploy/autostart
./start_unitree_sdk.sh

Second:

cd ~/go1_gym/go1_gym_deploy/docker
sudo make autostart

The robot will wait for you to press [R2], then calibrate, then wait for a second press of [R2] before running the control loop.

The RC Mapping

RC Mapping The RC mapping is depicted above.

Deploying a Custom Model

After training a custom model, it will be saved in the runs folder (https://github.com/Improbable-AI/walk-these-ways/tree/master/runs/). Note the relative location of your custom model of the train folder (for the default policy), it's gait-conditioned-agility/pretrain-v0/train. We'll denote this as $PDIR.

To play the custom model in simulation first, replace the line https://github.com/Improbable-AI/walk-these-ways/blob/master/scripts/play.py#L97 with label = "$PDIR".

To deploy on the robot, replace the line https://github.com/Improbable-AI/walk-these-ways/blob/master/go1_gym_deploy/scripts/deploy_policy.py#L73 with label = "$PDIR". Then re-run the send_to_unitree.sh script to update the files on the robot.

Logging and Debugging

Coming soon

Analyzing Real-world Performance

Coming soon

Debugging Common Errors

Bug Solution First report
Out of disk space If you run out of disk space during cd ~/go1_gym/go1_gym_deploy/installer && ./install_deployment_code.sh consider changing the script to use 192.168.123.13 instead (at least in my Go1 Edu with 3 Jetson nano, I only had the required disk space to copy the tar and extract the image in only 192.168.123.13). Alternatively, consider deploying on an external PC. #7
lcm_position syntax error When deploying with sudo ./start_unitree_sdk.sh on an external PC/NUC, if you get the following error: ./lcm_position: 1: Syntax error: word unexpected (expecting ")"), It is likely because the ./lcm_position has been compiled for ARM aarch64 (to run on the jetson), please recompile it for your architecture(external PC/ NUC) using https://github.com/Improbable-AI/unitree_legged_sdk. #7

More Repositories

1

VisionProTeleop

VisionOS App + Python Library to stream head / wrist / finger tracking data from Vision Pro to any robots.
Swift
356
star
2

rapid-locomotion-rl

Code for Rapid Locomotion via Reinforcement Learning
Python
162
star
3

dribblebot

Code release accompanying DribbleBot: Dynamic Legged Manipulation in the Wild
Python
91
star
4

dexenv

Code for Visual Dexterity: In-Hand Reorientation of Novel and Complex Object Shapes (Science Robotics)
Python
77
star
5

eipo

Official codebase for Redeeming Intrinsic Rewards via Constrained Policy Optimization
Python
75
star
6

airobot

A python library for robot learning - An extension to PyRobot
Python
74
star
7

pql

Parallel Q-Learning: Scaling Off-policy Reinforcement Learning under Massively Parallel Simulation
Python
50
star
8

curiosity_redteam

Official implementation of ICLR'24 paper, "Curiosity-driven Red Teaming for Large Language Models" (https://openreview.net/pdf?id=4KqkizXgXU)
Jupyter Notebook
43
star
9

Stubborn

Python
36
star
10

human-guided-exploration

Official codebase for Human Guided Exploration (HuGE)
Python
21
star
11

dw-offline-rl

Official implementation of NeurIPS'23 paper, Beyond Uniform Sampling: Offline Reinforcement Learning with Imbalanced Datasets
Python
16
star
12

harness-offline-rl

Official implementation of Harnessing Mixed Offline Reinforcement Learning Datasets via Trajectory Reweighting
Python
14
star
13

curiosity_baselines

An open source reinforcement learning codebase with a variety of intrinsic exploration methods implemented in PyTorch.
Python
10
star
14

learning-compliance

4
star
15

monkey-job-runner

Monkey Job Runner
Python
2
star
16

ter

TER codebase for release
Python
1
star
17

bvn

Official implementation of bilinear value networks
Python
1
star