• DocumentCode
    716863
  • Title

    Decoupled multiagent path planning via incremental sequential convex programming

  • Author

    Yufan Chen ; Cutler, Mark ; How, Jonathan P.

  • Author_Institution
    Lab. of Inf. & Decision Syst., Massachusetts Inst. of Technol., Cambridge, MA, USA
  • fYear
    2015
  • fDate
    26-30 May 2015
  • Firstpage
    5954
  • Lastpage
    5961
  • Abstract
    This paper presents a multiagent path planning algorithm based on sequential convex programming (SCP) that finds locally optimal trajectories. Previous work using SCP efficiently computes motion plans in convex spaces with no static obstacles. In many scenarios where the spaces are non-convex, previous SCP-based algorithms failed to find feasible solutions because the convex approximation of collision constraints leads to forming a sequence of infeasible optimization problems. This paper addresses this problem by tightening collision constraints incrementally, thus forming a sequence of more relaxed, feasible intermediate optimization problems. We show that the proposed algorithm increases the probability of finding feasible trajectories by 33% for teams of more than three vehicles in non-convex environments. Further, we show that decoupling the multiagent optimization problem to a number of single-agent optimization problems leads to significant improvement in computational tractability. We develop a decoupled implementation of the proposed algorithm, abbreviated dec-iSCP. We show that dec-iSCP runs 14% faster and finds feasible trajectories with higher probability than a decoupled implementation of previous SCP-based algorithms. The proposed algorithm is real-time implementable and is validated through hardware experiments on a team of quadrotors.
  • Keywords
    convex programming; multi-agent systems; multi-robot systems; path planning; SCP-based algorithms; collision constraints; convex approximation; convex spaces; dec-iSCP; decoupled multiagent path planning algorithm; incremental sequential convex programming; infeasible optimization problems; local optimal trajectory; motion planning; multiagent optimization problem; nonconvex environments; relaxed feasible intermediate optimization problems; single-agent optimization problems; Approximation algorithms; Approximation methods; Optimization; Time factors; Trajectory; Vehicles;
  • fLanguage
    English
  • Publisher
    ieee
  • Conference_Titel
    Robotics and Automation (ICRA), 2015 IEEE International Conference on
  • Conference_Location
    Seattle, WA
  • Type

    conf

  • DOI
    10.1109/ICRA.2015.7140034
  • Filename
    7140034