Abstract. We address a fundamental mismatch between the combinations of dynamics that occur in cyber-physical systems and the limited kinds of dynamics supported in analysis. Modern applications combine communication, computation, and control. They may even form dynamic distributed networks, where neither structure nor dimension stay the same while the system follows hybrid dynamics, i.e., mixed discrete and continuous dynamics. We provide the logical foundations for closing this analytic gap. We develop a formal model for distributed hybrid systems. It combines quantified differential equations with quantified assignments and dynamic dimensionality-changes. We introduce a dynamic logic for verifying distributed hybrid systems and present a...
Abstract. Ahybrid system is a dynamical system with both discrete and continuous state changes. For ...
Logic is a powerful tool for analyzing and verifying systems, including programs, discrete systems, ...
In contrast to what we know about controlling, verifying and reasoning about discrete state transiti...
We address a fundamental mismatch between the combinations of dynamics that occur in cyber-physical ...
We address the verification problem for distributed hybrid systems with nontrivial dynamics. Conside...
We introduce a first-order dynamic logic for reasoning about systems with discrete and continuous st...
Formal verification techniques are used routinely in finite-state digital circuits. Theorem proving ...
Hybrid systems are a fusion of continuous dynamical systems and discrete dynamical systems. They fre...
Abstract We formalize the soundness theorem for differential dynamic logic, a logic for verifying hy...
We present a formal proof of collision avoidance for a simple distributed hybrid system consisting o...
Cyber-physical systems are often safety-critical and their correctness is crucial, as in the case of...
We introduce a hybrid variant of a dynamic logic with continuous state transitions along differentia...
AbstractIn this paper, we present Hybrid Event B, a formal language for modeling hybrid systems. Spe...
ions ? Anuj Puri and Pravin Varaiya Department of Electrical Engineering and Computer Science, Uni...
Hybrid systems air he/erogenous dynamical systems cliaracterized by interacting continuous and discr...
Abstract. Ahybrid system is a dynamical system with both discrete and continuous state changes. For ...
Logic is a powerful tool for analyzing and verifying systems, including programs, discrete systems, ...
In contrast to what we know about controlling, verifying and reasoning about discrete state transiti...
We address a fundamental mismatch between the combinations of dynamics that occur in cyber-physical ...
We address the verification problem for distributed hybrid systems with nontrivial dynamics. Conside...
We introduce a first-order dynamic logic for reasoning about systems with discrete and continuous st...
Formal verification techniques are used routinely in finite-state digital circuits. Theorem proving ...
Hybrid systems are a fusion of continuous dynamical systems and discrete dynamical systems. They fre...
Abstract We formalize the soundness theorem for differential dynamic logic, a logic for verifying hy...
We present a formal proof of collision avoidance for a simple distributed hybrid system consisting o...
Cyber-physical systems are often safety-critical and their correctness is crucial, as in the case of...
We introduce a hybrid variant of a dynamic logic with continuous state transitions along differentia...
AbstractIn this paper, we present Hybrid Event B, a formal language for modeling hybrid systems. Spe...
ions ? Anuj Puri and Pravin Varaiya Department of Electrical Engineering and Computer Science, Uni...
Hybrid systems air he/erogenous dynamical systems cliaracterized by interacting continuous and discr...
Abstract. Ahybrid system is a dynamical system with both discrete and continuous state changes. For ...
Logic is a powerful tool for analyzing and verifying systems, including programs, discrete systems, ...
In contrast to what we know about controlling, verifying and reasoning about discrete state transiti...
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