Freestyle Quadcopter Flight in Pybullet with Gym and (soon) PettingZoo APIs
Project description
PyFlyt - UAV Flight Simulator Gymnasium Environments for Reinforcement Learning Research
This is a library for testing reinforcement learning algorithms on UAVs. This repo is still under development. We are also actively looking for users and developers, if this sounds like you, don't hesitate to get in touch!
PyFlyt currently supports two separate UAV platforms:
-
QuadX UAV
- Inspired by the original pybullet drones by University of Toronto's Dynamic Systems Lab
- Quadrotor UAV in the X configuration
- Actual full cascaded PID flight controller implementations for each drone.
- Actual motor RPM simulation using first order differential equation.
- Modular control structure
- For developers - 8 implemented flight modes that use tuned cascaded PID flight controllers, available in
PyFlyt/core/drones/quadx.py.
-
Fixedwing UAV
- Flight model designed for a small fixed wing UAV (< 10 Kg)
- Assumes a conventional tube and wing design
- Single puller propeller with thrust line passing through CG
- Aerofoil characteristics derived from the paper: Real-time modeling of agile fixed-wing UAV aerodynamics
Table of Contents
Installation
pip3 install pyflyt
Usage
Usage is similar to any other Gymnasium and (soon) PettingZoo environment:
import gymnasium
import PyFlyt.gym_envs
env = gymnasium.make("PyFlyt/QuadX-Hover-v0")
# ommit the below line to remove renderring and let
# the simulation go as fast as possible
env.render()
obs = env.reset()
done = False
while not done:
observation, reward, termination, truncation, info = env.step(env.action_space.sample())
Environments
PyFlyt/QuadX-Hover-v0
A simple environment where an agent can learn to hover. The environment ends when either the quadcopter collides with the ground or exits the permitted flight dome.
env = gymnasium.make(
"PyFlyt/QuadX-Hover-v0",
flight_dome_size: float = 3.0,
max_duration_seconds: float = 10.0,
angle_representation: str = "quaternion",
agent_hz: int = 40,
render_mode: None | str = None,
)
angle_representationcan be either"quaternion"or"euler".
render_modecan be either"human"orNone.
PyFlyt/QuadX-Waypoints-v0
A simple environment where the goal is to fly the quadrotor to a collection of random waypoints in space within the permitted flight dome. The environment ends when either the quadrotor collides with the ground or exits the permitted flight dome.
env = gymnasium.make(
"PyFlyt/QuadX-Waypoints-v0",
sparse_reward: bool = False,
num_targets: int = 4,
use_yaw_targets: bool = False,
goal_reach_distance: float = 0.2,
goal_reach_angle: float = 0.1,
flight_dome_size: float = 5.0,
max_duration_seconds: float = 10.0,
angle_representation: str = "quaternion",
agent_hz: int = 30,
render_mode: None | str = None,
)
angle_representationcan be either"quaternion"or"euler".
render_modecan be either"human"orNone.
PyFlyt/Fixedwing-Waypoints-v0
A simple environment where the goal is to fly a fixedwing aircraft towards set of random waypionts in space within the permitted flight dome. The environment ends when either the aircraft collides with the ground or exits the permitted flight dome.
env = gymnasium.make(
"PyFlyt/Fixedwing-Waypoints-v0",
sparse_reward: bool = False,
num_targets: int = 4,
goal_reach_distance: float = 2.0,
flight_dome_size: float = 100.0,
max_duration_seconds: float = 120.0,
angle_representation: str = "quaternion",
agent_hz: int = 30,
render_mode: None | str = None,
)
angle_representationcan be either"quaternion"or"euler".
render_modecan be either"human"orNone.
Non-Gymnasium examples
If you're not interested in RL but want to use the library for your own research, we provide a bunch of example code in examples/ that you can run with python3 examples/***.py in macOS and Linux.
PyFlyt also has naive support for flying real Crazyflie drones.
These examples are provided under examples/crazyflie/***.py.
The library is built using CrazyFlie drones, check out the documentation.
These scripts are built with as little dependencies as possible, but enable interfacing with real (using the CrazyPA module) or virtual drones easy.
Simulation Only
sim_single.py
Simulates a single drone in the pybullet env with position control.
sim_swarm.py
Simulates a swarm of drones in the pybullet env with velocity control.
sim_cube.py
Simulates a swarm of drones in a spinning cube.
Hardware Only
fly_single.py
Flies a real Crazyflie, check out the documentation and how to connect to get your URI(s) and modify them in line 18.
fly_swarm.py
Flies a real Crazyflie swarm, same as the previous example, but now takes in a list of URIs.
Simulation or Hardware
sim_n_fly_single.py
Simple script that can be used to fly a single crazyflie in sim or with a real drone using either the --hardware or --simulate args.
sim_n_fly_multiple.py
Simple script that can be used to fly a swarm of crazyflies in sim or with real drones using either the --hardware or --simulate args.
sim_n_fly_cube_from_scratch.py
Simple script that can be used to fly a swarm of crazyflies in sim or with real drones using either the --hardware or --simulate args, and forms the same spinning cube from takeoff as in sim_cube.py.
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