Skip to content

Latest commit

 

History

History
66 lines (49 loc) · 3.44 KB

README.md

File metadata and controls

66 lines (49 loc) · 3.44 KB

D* Lite incremental pathplanning algorithm for robotics

Implementation of the D* lite algorithm for pathplanning in Python and eventually also C++

Build Status version Maintenance GitHub pull-requests GitHub pull-requests closed ViewCount License: MIT

This software is an implementation of the D*-Lite algorithm as explained in Koenig, 2002. The D* Lite algorithm was developed by Sven Koenig and Maxim Likhachev for a faster more lightweight alternative to the D* algorithm (developed by Anthony Stentz in 1995).

Dependencies

  • pip install pygame
  • pip install numpy

install poetry package mananger and virtual env (or use pipenv):

you can use pipenv or poetry to active virtual env.

$ pip install poetry
$ cd /d-star-lite/python
$ poetry install
$ poetry shell
$ python main.py

Commands

  • [Space] - move robot along line
  • [left click] - place obstacle
  • [right click] - remove obstacle
  • s_start, s_goal and view range can be changed in main.py

The cell colors are as follows:

  • Red - shortest path
  • Green - goal vertex
  • grey - obstacle
  • white - unoccupied

idea

The version of D* Lite that I implemented works by bascially running A* search in reverse starting from the goal and attempting to work back to the start. The solver then gives out the current solution and waits for some kind of change in the weights or obstacles that it is presented with. As opposed to repeated A* search, the D* Lite algorithm avoids replanning from scratch and incrementally repair path keeping its modifications local around robot pose.

This is the optimized version as explained in Figure 4 of the paper.

Main concepts

  1. Switched search direction: search from goalto the current vertex. If a change in edge cost is detected during traversal (around the current robot pose), only few nodes near the goal (=start) need to be updated.
  2. These nodes are nodes those goal distances have changed or not been caculated before and are relevant to recalculate the new shortest path to the goal.
  3. Incremental heuristic search algorithms: able to focus and build upon previous solutions

Pseudo code, D* Lite optimized version

D* Lite optimized

References:

Improved Fast Replanning for Robot Navigation in Unknown Terrain
Sven Koenig, Maxim Likhachev
Technical Report GIT-COGSCI-2002/3,
Georgia Institute of Technology, 2002.