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Decentralized Control for Discrete-time Mean-Field Systems with Multiple Controllers of Delayed Information

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arxiv 2309.01341 v1 pith:KPXBN4HT submitted 2023-09-04 math.OC

Decentralized Control for Discrete-time Mean-Field Systems with Multiple Controllers of Delayed Information

classification math.OC
keywords controlcontrollersinformationdecentralizeddifferentfieldmeanmultiple
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In this paper, the finite horizon asymmetric information linear quadratic (LQ) control problem is investigated for a discrete-time mean field system. Different from previous works, multiple controllers with different information sets are involved in the mean field system dynamics. The coupling of different controllers makes it quite difficult in finding the optimal control strategy. Fortunately, by applying the Pontryagin's maximum principle, the corresponding decentralized control problem of the finite horizon is investigated. The contributions of this paper can be concluded as: For the first time, based on the solution of a group of mean-field forward and backward stochastic difference equations (MF-FBSDEs), the necessary and sufficient solvability conditions are derived for the asymmetric information LQ control for the mean field system with multiple controllers. Furthermore, by the use of an innovative orthogonal decomposition approach, the optimal decentralized control strategy is derived, which is based on the solution to a non-symmetric Riccati-type equation.

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