Satisfaction probabilities for homogeneous stochastic MAS under cLTL admit DFA-based tensor decomposition, enabling a dual-tree value iteration framework that reduces redundant dynamic programming computations.
Correct-by-Design Control Synthesis of Stochastic Multi-agent Systems: a Robust Tensor-based Solution
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abstract
Discrete-time stochastic systems with continuous spaces are hard to verify and control, even with MDP abstractions due to the curse of dimensionality. We propose an abstraction-based framework with robust dynamic programming mappings that deliver control strategies with provable lower bounds on temporal-logic satisfaction, quantified via approximate stochastic simulation relations. Exploiting decoupled dynamics, we reveal a Canonical Polyadic Decomposition tensor structure in value functions that makes dynamic programming scalable. The proposed method provides correct-by-design probabilistic guarantees for temporal logic specifications. We validate our results on continuous-state linear stochastic systems.
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Compressing Correct-by-Design Synthesis for Stochastic Homogeneous Multi-Agent Systems with Counting LTL
Satisfaction probabilities for homogeneous stochastic MAS under cLTL admit DFA-based tensor decomposition, enabling a dual-tree value iteration framework that reduces redundant dynamic programming computations.