• DocumentCode
    2919661
  • Title

    Distributed Control of Multi-robot Formation Based on Spatially Interconnected Model

  • Author

    Hui Li ; Qing-he Wu ; Huang, Huang

  • Author_Institution
    Dept. of Autom. Control, Beijing Inst. of Technol., Beijing
  • fYear
    2009
  • fDate
    20-22 Feb. 2009
  • Firstpage
    200
  • Lastpage
    204
  • Abstract
    This paper addresses the control of multi-robot formation in 2-dimension plane. Dynamic extension is used to linearize the robotpsilas kinematic model. Since the formation models, which use the error of robotspsila real positions and speeds with respect to their desired values as the controlled valuables, are coupled systems, a spatial shift operator is introduced to model them as spatially interconnected systems. Then distributed controllers which have the same structure as the plants and will simplify the computation compared with centralized controllers are designed. The controllers are dynamic output feedback controllers and can not only stabilize the nominal formation system but also robustly stabilize a perturbed version of the system. The design procedure is presented which involve the application of convex optimization tools, i.e. linear matrix inequalities. The experimental results are simulated in MATLAB software and are confirmed with the formation of Team AmigoBot Mobile Robots.
  • Keywords
    control system synthesis; convex programming; distributed control; feedback; linear matrix inequalities; mobile robots; multi-robot systems; position control; robot dynamics; robot kinematics; stability; 2D plane; convex optimization; coupled systems; design procedure; distributed controller; dynamic extension; dynamic output feedback controller; linear matrix inequalities; multirobot formation; nominal formation system; robot kinematic model; robust stability; spatial shift operator; spatially interconnected model; spatially interconnected systems; Centralized control; Control systems; Distributed computing; Distributed control; Error correction; Interconnected systems; Kinematics; Mathematical model; Output feedback; Robots; distributed control; multi-robot formation; spatially interconnected systems;
  • fLanguage
    English
  • Publisher
    ieee
  • Conference_Titel
    Electronic Computer Technology, 2009 International Conference on
  • Conference_Location
    Macau
  • Print_ISBN
    978-0-7695-3559-3
  • Type

    conf

  • DOI
    10.1109/ICECT.2009.72
  • Filename
    4795950