Python codes for robotics algorithm.

• What is this?
• Requirements
• How to use
• Localization
  • Extended Kalman Filter localization
  • Unscented Kalman Filter localization
  • Particle filter localization
  • Histogram filter localization
• Mapping
  • Gaussian grid map
  • Ray casting grid map
  • k-means object clustering
  • Object shape recognition using circle fitting
• SLAM
  • Iterative Closest Point (ICP) Matching
  • EKF SLAM
  • FastSLAM 1.0
  • FastSLAM 2.0
  • Graph based SLAM
• Path Planning
  • Dynamic Window Approach
  • Grid based search
    • Dijkstra algorithm
    • A* algorithm
    • Potential Field algorithm
  • Model Predictive Trajectory Generator
    • Path optimization sample
    • Lookup table generation sample
  • State Lattice Planning
    • Uniform polar sampling
    • Biased polar sampling
    • Lane sampling
  • Probabilistic Road-Map (PRM) planning
  • Voronoi Road-Map planning
  • Rapidly-Exploring Random Trees (RRT)
    • Basic RRT
    • RRT*
    • RRT with dubins path
    • RRT* with dubins path
    • RRT* with reeds-sheep path
    • Informed RRT*
    • Batch Informed RRT*
    • Closed Loop RRT*
    • LQR-RRT*
  • Cubic spline planning
  • B-Spline planning
  • Bezier path planning
  • Quintic polynomials planning
  • Dubins path planning
  • Reeds Shepp planning
  • LQR based path planning
  • Optimal Trajectory in a Frenet Frame
• Path tracking
  • Pure pursuit tracking
  • Stanley control
  • Rear wheel feedback control
  • Linear–quadratic regulator (LQR) steering control
  • Linear–quadratic regulator (LQR) speed and steering control
  • Model predictive speed and steering control
• License
• Contribution
• Support
• Authors

This is a Python code collection of robotics algorithms, especially autonomous navigation.

Feature:

1. Widely used and practical algorithms are selected.

2. Minimum dependency.

3. Easy to read for understanding each algorithm's basic idea.

• Python 3.6.x

• numpy

• scipy

• matplotlib

• pandas

• cvxpy 0.4.x

1. Install the required libraries.

2. Clone this repo.

3. Execute python script in each directory.

4. Add star to this repo if you like it 😃.

This is a sensor fusion localization with Extended Kalman Filter(EKF).

The blue line is true trajectory, the black line is dead reckoning trajectory,

the green point is positioning observation (ex. GPS), and the red line is estimated trajectory with EKF.

The red ellipse is estimated covariance ellipse with EKF.

Ref:

• PROBABILISTIC ROBOTICS

This is a sensor fusion localization with Unscented Kalman Filter(UKF).

The lines and points are same meaning of the EKF simulation.

Ref:

• Discriminatively Trained Unscented Kalman Filter for Mobile Robot Localization

This is a sensor fusion localization with Particle Filter(PF).

The blue line is true trajectory, the black line is dead reckoning trajectory,

and the red line is estimated trajectory with PF.

It is assumed that the robot can measure a distance from landmarks (RFID).

This measurements are used for PF localization.

Ref:

• PROBABILISTIC ROBOTICS

This is a 2D localization example with Histogram filter.

The red cross is true position, black points are RFID positions.

The blue grid shows a position probability of histogram filter.

In this simulation, x,y are unknown, yaw is known.

The filter integrates speed input and range observations from RFID for localization.

Initial position is not needed.

Ref:

• PROBABILISTIC ROBOTICS

This is a 2D Gaussian grid mapping example.

This is a 2D ray casting grid mapping example.

This is a 2D object clustering with k-means algorithm.

This is a object shape recognition using circle fitting.

The blue circle is the true object shape.

The red crosses are observations from a ranging sensor.

The red circle is the estimated object shape using circle fitting.

Simultaneous Localization and Mapping(SLAM) examples

This is a 2D ICP matching example with singular value decomposition.

It can calculate a rotation matrix and a translation vector between points to points.

Ref:

• Introduction to Mobile Robotics: Iterative Closest Point Algorithm

This is a Extended Kalman Filter based SLAM example.

The blue line is ground truth, the black line is dead reckoning, the red line is the estimated trajectory with EKF SLAM.

The green cross are estimated landmarks.

Ref:

• PROBABILISTIC ROBOTICS

This is a feature based SLAM example using FastSLAM 1.0.

The blue line is ground truth, the black line is dead reckoning, the red line is the estimated trajectory with FastSLAM.

The red points are particles of FastSLAM.

Black points are landmarks, blue crosses are estimated landmark positions by FastSLAM.

Ref:

• PROBABILISTIC ROBOTICS

• SLAM simulations by Tim Bailey

This is a feature based SLAM example using FastSLAM 2.0.

The animation has same meanings as one of FastSLAM 1.0.

Ref:

• PROBABILISTIC ROBOTICS

• SLAM simulations by Tim Bailey

This is a graph based SLAM example.

The blue line is ground truth.

The black line is dead reckoning.

The red line is the estimated trajectory with Graph based SLAM.

The black stars are landmarks for graph edge generation.

Ref:

• A Tutorial on Graph-Based SLAM

This is a 2D navigation sample code with Dynamic Window Approach.

• The Dynamic Window Approach to Collision Avoidance

This is a 2D grid based shortest path planning with Dijkstra's algorithm.

In the animation, cyan points are searched nodes.

This is a 2D grid based shortest path planning with A star algorithm.

In the animation, cyan points are searched nodes.

It's heuristic is 2D Euclid distance.

This is a 2D grid based path planning with Potential Field algorithm.

In the animation, the blue heat map shows potential value on each grid.

Ref:

• Robotic Motion Planning:Potential Functions

This is a path optimization sample on model predictive trajectory generator.

This algorithm is used for state lattice planner.

Ref:

• Optimal rough terrain trajectory generation for wheeled mobile robots

This script is a path planning code with state lattice planning.

This code uses the model predictive trajectory generator to solve boundary problem.

Ref:

• Optimal rough terrain trajectory generation for wheeled mobile robots

• State Space Sampling of Feasible Motions for High-Performance Mobile Robot Navigation in Complex Environments

This PRM planner uses Dijkstra method for graph search.

In the animation, blue points are sampled points,

Cyan crosses means searched points with Dijkstra method,

The red line is the final path of PRM.

Ref:

• Probabilistic roadmap - Wikipedia

This Voronoi road-map planner uses Dijkstra method for graph search.

In the animation, blue points are Voronoi points,

Cyan crosses means searched points with Dijkstra method,

The red line is the final path of Vornoi Road-Map.

Ref:

• Robotic Motion Planning

This is a simple path planning code with Rapidly-Exploring Random Trees (RRT)

Black circles are obstacles, green line is a searched tree, red crosses are start and goal positions.

This is a path planning code with RRT*

Black circles are obstacles, green line is a searched tree, red crosses are start and goal positions.

Ref:

• Incremental Sampling-based Algorithms for Optimal Motion Planning

• Sampling-based Algorithms for Optimal Motion Planning

Path planning for a car robot with RRT and dubins path planner.

Path planning for a car robot with RRT* and dubins path planner.

)

Path planning for a car robot with RRT* and reeds sheep path planner.

)

This is a path planning code with Informed RRT*.

The cyan ellipse is the heuristic sampling domein of Informed RRT*.

Ref:

• Informed RRT*: Optimal Sampling-based Path Planning Focused via Direct Sampling of an Admissible Ellipsoidal Heuristic

)

This is a path planning code with Batch Informed RRT*.

Ref:

• Batch Informed Trees (BIT*): Sampling-based Optimal Planning via the Heuristically Guided Search of Implicit Random Geometric Graphs

A vehicle model based path planning with closed loop RRT*.

In this code, pure-pursuit algorithm is used for steering control,

PID is used for speed control.

Ref:

• Motion Planning in Complex Environments using Closed-loop Prediction

• Real-time Motion Planning with Applications to Autonomous Urban Driving

• [1601.06326] Sampling-based Algorithms for Optimal Motion Planning Using Closed-loop Prediction

This is a path planning simulation with LQR-RRT*.

A double integrator motion model is used for LQR local planner.

Ref:

• LQR-RRT*: Optimal Sampling-Based Motion Planning with Automatically Derived Extension Heuristics

• MahanFathi/LQR-RRTstar: LQR-RRT* method is used for random motion planning of a simple pendulum in it's phase plot

A sample code for cubic path planning.

This code generates a curvature continuous path based on x-y waypoints with cubic spline.

Heading angle of each point can be also calculated analytically.

This is a path planning with B-Spline curse.

If you input waypoints, it generates a smooth path with B-Spline curve.

The final course should be on the first and last waypoints.

Ref:

• B-spline - Wikipedia

A sample code of Bezier path planning.

It is based on 4 control points Beier path.

If you change the offset distance from start and end point,

You can get different Beizer course:

Ref:

• Continuous Curvature Path Generation Based on Bezier Curves for Autonomous Vehicles

Motion planning with quintic polynomials.

It can calculate 2D path, velocity, and acceleration profile based on quintic polynomials.

Ref:

• Local Path Planning And Motion Control For Agv In Positioning

A sample code for Dubins path planning.

Ref:

• Dubins path - Wikipedia

A sample code with Reeds Shepp path planning.

Ref:

• 15.3.2 Reeds-Shepp Curves

• optimal paths for a car that goes both forwards and backwards

• ghliu/pyReedsShepp: Implementation of Reeds Shepp curve.

A sample code using LQR based path planning for double integrator model.

This is optimal trajectory generation in a Frenet Frame.

The cyan line is the target course and black crosses are obstacles.

The red line is predicted path.

Ref:

• Optimal Trajectory Generation for Dynamic Street Scenarios in a Frenet Frame

• Optimal trajectory generation for dynamic street scenarios in a Frenet Frame

Path tracking simulation with pure pursuit steering control and PID speed control.

The red line is a target course, the green cross means the target point for pure pursuit control, the blue line is the tracking.

Ref:

• A Survey of Motion Planning and Control Techniques for Self-driving Urban Vehicles

Path tracking simulation with Stanley steering control and PID speed control.

Ref:

• Stanley: The robot that won the DARPA grand challenge

• Automatic Steering Methods for Autonomous Automobile Path Tracking

Path tracking simulation with rear wheel feedback steering control and PID speed control.

Ref:

• A Survey of Motion Planning and Control Techniques for Self-driving Urban Vehicles

Path tracking simulation with LQR steering control and PID speed control.

Ref:

• ApolloAuto/apollo: An open autonomous driving platform

Path tracking simulation with LQR speed and steering control.

Ref:

• Towards fully autonomous driving: Systems and algorithms - IEEE Conference Publication

Path tracking simulation with iterative linear model predictive speed and steering control.

This code uses cvxpy as an optimization modeling tool.

• Welcome to CVXPY

Ref:

• Vehicle Dynamics and Control | Rajesh Rajamani | Springer

• MPC Course Material - MPC Lab @ UC-Berkeley

MIT

A small PR like bug fix is welcome.

If your PR is merged multiple times, I will add your account to the author list.

You can support this project financially via Patreon.

You can get e-mail technical supports about the codes if you are being patron.

• Atsushi Sakai is creating Open Source Software | Patreon

PayPal donation is also welcome.

• Atsushi Sakai (@Atsushi_twi)

• Daniel Ingram

• Joe Dinius

• Karan Chawla

• Antonin RAFFIN