Relations between information theory, robustness, and statistical mechanics of stochastic systems
PublisherAffiliation: Sch. of Info. Technol. and Eng., University of Ottawa, 161 Louis Pasteur, A519, Ottawa, Ont. K1N 6N5, Canada
Affiliation: Electrical Engineering Department, University of Cyprus, 75 Kallipoleos Avenue, Nicosia, Cyprus
Affiliation: Sch. of Info. Technol. and Eng., University of Ottawa, 800 King Edward Ave., Ottawa, Ont. K1N 6N5, Canada
Affiliation: Mechanical Engineering Department, University of Cyprus, 75 Kallipoleos Avenue, Nicosia, Cyprus
Correspondence Address: Charalambous, C.D.
Sch. of Info. Technol. and Eng., University of Ottawa, 161 Louis Pasteur, A519, Ottawa, Ont. K1N 6N5, Canada
SourceProceedings of the IEEE Conference on Decision and Control
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The fundamental question, which will be addressed in this talk are the relations between dissipation, which is a concept of robustness, entropy rate, which is a concept of information theory, and statistical mechanics. Dissipation is a concept which is used in the theory and applications of robustness of filtering and control of uncertain systems. In thermodynamics, when a system is not in equilibrium with its surroundings there exists a potential of producing useful work. Dissipation is the part of this potential that is not tranformable to useful work. On the other hand, entropy is fundamental concept on which information theory and in general telecommunication systems are founded on. Entropy rate is a macroscopic property of thermodynamic systems, that quantifies dissipation through the Clausius inequality and irreversible processes. In addition entropy measures the number of microstates, different configurations of the phase space, that correspond to a thermodynamic macrostate of certain entropy value. In this presentation statistical mechanics concepts will be used to bring about the close relationship between entropy and dissipation and in particular, the implication of this relationship, in computing the induced norm associated with disturbance attenuation problems.