Title :
Optimal trajectories for underwater vehicles by quantization and stochastic control
Author :
Huilong Zhang ; de Saporta, Benoite ; Dufour, F. ; Laneuville, Dann ; Negre, Adrien
Author_Institution :
IMB, Univ. Bordeaux, Bordeaux, France
Abstract :
We present in this paper a numerical method which computes the trajectory of a vehicle subject to some mission objectives. The method is applied to a submarine whose goal is to best detect one or several targets (we consider signal attenuation due to acoustic propagation) or/and to minimize its own detection range perceived by the other targets. Our approach is based on dynamic programming of a finite horizon Markov decision process. The position and the velocity of the targets are supposed to be known only up to a random estimation error, as a Kalman type filter is used to estimate these quantities from the measurements given by the on board sonar. We also take into account the information on the environment through a sound propagation code. A quantization method is applied to fully discretize the problem and solve it numerically.
Keywords :
Kalman filters; Markov processes; acoustic signal processing; dynamic programming; quantisation (signal); stochastic systems; trajectory control; underwater vehicles; Kalman type filter; acoustic propagation; dynamic programming; finite horizon Markov decision process; numerical method; optimal trajectory; quantization method; random estimation error; signal attenuation; sound propagation code; stochastic control; submarine; underwater vehicles; Dynamic programming; Markov processes; Optimal control; Optimization; Quantization (signal); Trajectory; Underwater vehicles; Dynamic programming; Markov decision processes; Non linear filtering; Quantization; Underwater acoustic warfare;
Conference_Titel :
Information Fusion (FUSION), 2014 17th International Conference on
Conference_Location :
Salamanca
