This work targets the development of an efficient abstraction method for formal analysis and control synthesis of discretetime stochastic hybrid systems (shs) with linear dynamics. The focus is on temporal logic specifications, both over finite and infinite time horizons. The framework constructs a finite abstraction as a class of uncertain Markov models known as interval Markov decision process (imdp). Then, a strategy that maximizes the satisfaction probability of the given specification is synthesized over the imdp and mapped to the underlying shs. In contrast to existing formal approaches, which are by and large limited to finite-time properties and rely on conservative over-approximations, we show that the exact abstraction error can b...
We present a method for designing a robust control policy for an uncertain system subject to tempora...
Abstract—We present a constructive procedure for obtaining a finite approximate abstraction of a dis...
Abstract. The objective of this study is to introduce an abstraction procedure that applies to a gen...
This work targets the development of an efficient abstraction method for formal analysis and control...
Stochastic hybrid systems involve the coupling of discrete, continuous, and probabilistic phenomena,...
Discrete-time stochastic systems are an essential modelling tool for many engineering systems. We co...
This work introduces a theoretical framework and a scalable computational method for formal analysis...
Capturing uncertainty in models of complex dynamical systems is crucial to designing safe controller...
The essential step of abstraction-based control synthesis for nonlinear systems to satisfy a given s...
Results on approximate model-checking of Stochastic Hybrid Sys-tems (SHS) against general temporal s...
We present a method for designing robust controllers for dynamical systems with linear temporal logi...
The formal verification and controller synthesis for general Markov decision processes (gMDPs) that ...
The problem of control synthesis to maximize the probability of satisfying automata specifications f...
We synthesize controllers for discrete-time stochastic hybrid systems such that the probability of s...
We present a method for designing a robust control policy for an uncertain system subject to tempora...
Abstract—We present a constructive procedure for obtaining a finite approximate abstraction of a dis...
Abstract. The objective of this study is to introduce an abstraction procedure that applies to a gen...
This work targets the development of an efficient abstraction method for formal analysis and control...
Stochastic hybrid systems involve the coupling of discrete, continuous, and probabilistic phenomena,...
Discrete-time stochastic systems are an essential modelling tool for many engineering systems. We co...
This work introduces a theoretical framework and a scalable computational method for formal analysis...
Capturing uncertainty in models of complex dynamical systems is crucial to designing safe controller...
The essential step of abstraction-based control synthesis for nonlinear systems to satisfy a given s...
Results on approximate model-checking of Stochastic Hybrid Sys-tems (SHS) against general temporal s...
We present a method for designing robust controllers for dynamical systems with linear temporal logi...
The formal verification and controller synthesis for general Markov decision processes (gMDPs) that ...
The problem of control synthesis to maximize the probability of satisfying automata specifications f...
We synthesize controllers for discrete-time stochastic hybrid systems such that the probability of s...
We present a method for designing a robust control policy for an uncertain system subject to tempora...
Abstract—We present a constructive procedure for obtaining a finite approximate abstraction of a dis...
Abstract. The objective of this study is to introduce an abstraction procedure that applies to a gen...