Theta: Any-Angle Path Planning on Grids

Theta: Any-Angle Path Planning on Grids

Grids with blocked and unblocked cells are often used to represent terrain in robotics and video games. However, paths formed by grid edges can be longer than true shortest paths in the terrain since their headings are artificially constrained. We present two new correct and complete any-angle path-...

Full description

Saved in:
Bibliographic Details
Published in:The Journal of artificial intelligence research Vol. 39; pp. 533 - 579
Main Authors: Daniel, K., Nash, A., Koenig, S., Felner, A.
Format: Journal Article
Language:English
Published: San Francisco AI Access Foundation 01-01-2010
Subjects:
Algorithms
Apexes
Artificial intelligence
Complexity
Computer & video games
Constraining
Path planning
Propagation
Robotics
Shortest-path problems
Terrain
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Grids with blocked and unblocked cells are often used to represent terrain in robotics and video games. However, paths formed by grid edges can be longer than true shortest paths in the terrain since their headings are artificially constrained. We present two new correct and complete any-angle path-planning algorithms that avoid this shortcoming. Basic Theta* and Angle-Propagation Theta* are both variants of A* that propagate information along grid edges without constraining paths to grid edges. Basic Theta* is simple to understand and implement, fast and finds short paths. However, it is not guaranteed to find true shortest paths. Angle-Propagation Theta* achieves a better worst-case complexity per vertex expansion than Basic Theta* by propagating angle ranges when it expands vertices, but is more complex, not as fast and finds slightly longer paths. We refer to Basic Theta* and Angle-Propagation Theta* collectively as Theta*. Theta* has unique properties, which we analyze in detail. We show experimentally that it finds shorter paths than both A* with post-smoothed paths and Field D* (the only other version of A* we know of that propagates information along grid edges without constraining paths to grid edges) with a runtime comparable to that of A* on grids. Finally, we extend Theta* to grids that contain unblocked cells with non-uniform traversal costs and introduce variants of Theta* which provide different tradeoffs between path length and runtime.
ISSN:1076-9757
1076-9757
1943-5037
DOI:10.1613/jair.2994