English

Lattice-based Motion Planning for a General 2-trailer system

Optimization and Control 2017-03-24 v2

Abstract

Motion planning for a general 2-trailer system poses a hard problem for any motion planning algorithm and previous methods have lacked any completeness or optimality guarantees. In this work we present a lattice-based motion planning framework for a general 2-trailer system that is resolution complete and resolution optimal. The solution will satisfy both differential and obstacle imposed constraints and is intended as a driver support system to automatically plan complicated maneuvers in backward and forward motion. The proposed framework relies on a precomputing step that is performed offline to generate a finite set of kinematically feasible motion primitives. These motion primitives are then used to create a regular state lattice that can be searched for a solution using standard graph-search algorithms. To make this graph-search problem tractable for real-time applications a novel parametrization of the reachable state space is proposed where each motion primitive moves the system from and to a selected set of circular equilibrium configurations. The approach is evaluated over three different scenarios and impressive real-time performance is achieved.

Keywords

Cite

@article{arxiv.1703.03616,
  title  = {Lattice-based Motion Planning for a General 2-trailer system},
  author = {Oskar Ljungqvist and Niclas Evestedt and Marcello Cirillo and Daniel Axehill and Olov Holmer},
  journal= {arXiv preprint arXiv:1703.03616},
  year   = {2017}
}
R2 v1 2026-06-22T18:42:09.171Z