Title :
Motion camouflage in a stochastic setting
Author :
Galloway, K.S. ; Justh, E.W. ; Krishnaprasad, P.S.
Author_Institution :
Maryland Univ., College Park
Abstract :
Recent work has formulated 2- and 3-dimensional models and steering control laws for motion camouflage, a stealthy pursuit strategy observed in nature. Here we extend the model to encompass the use of a high-gain pursuit law in the presence of sensor noise as well as in the case when the evader´s steering is driven by a stochastic process, demonstrating (in the planar setting) that motion camouflage is still accessible (in the mean) in finite time. We also discuss a family of admissible stochastic evader controls, laying out the groundwork for a future game-theoretic study of optimal evasion strategies.
Keywords :
game theory; stochastic processes; admissible stochastic evader control; evader steering; finite time; game theory; high-gain pursuit law; motion camouflage; optimal evasion; sensor noise; stochastic process; stochastic setting; Biological system modeling; Delay; Feedback; Insects; Microorganisms; Motion analysis; Motion control; Stochastic processes; Stochastic resonance; USA Councils;
Conference_Titel :
Decision and Control, 2007 46th IEEE Conference on
Conference_Location :
New Orleans, LA
Print_ISBN :
978-1-4244-1497-0
Electronic_ISBN :
0191-2216
DOI :
10.1109/CDC.2007.4434292
