Title :
A Differential Game Approach to Formation Control
Author_Institution :
Essex Univ., Colchester
Abstract :
This paper presents a differential game approach to formation control of mobile robots. The formation control is formulated as a linear-quadratic Nash differential game through the use of graph theory. Finite horizon cost function is discussed under the open-loop information structure. An open-loop Nash equilibrium solution is investigated by establishing existence and stability conditions of the solutions of coupled (asymmetrical) Riccati differential equations. Based on the finite horizon open-loop Nash equilibrium solution, a receding horizon approach is adopted to synthesize a state-feedback controller for the formation control. Mobile robots with double integrator dynamics are used in the formation control simulation. Simulation results are provided to justify the models and solutions.
Keywords :
Riccati equations; differential equations; differential games; graph theory; linear quadratic control; mobile robots; open loop systems; state feedback; Riccati differential equation; double integrator dynamics; finite horizon cost function; finite horizon open-loop Nash equilibrium solution; formation mobile robot control; graph theory; linear-quadratic Nash differential game; open-loop information structure; state-feedback controller; Cost function; Differential equations; Game theory; Graph theory; Mobile robots; Nash equilibrium; Open loop systems; Riccati equations; Robot control; Stability; Formation control; Nash equilibrium; linear-quadratic differential game;
Journal_Title :
Control Systems Technology, IEEE Transactions on
DOI :
10.1109/TCST.2007.899732
