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On the information properties of working used systems using dynamic signature
Author(s) -
Toomaj Abdolsaeed,
Chahkandi Majid,
Balakrishnan Narayanaswamy
Publication year - 2020
Publication title -
applied stochastic models in business and industry
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 0.413
H-Index - 40
eISSN - 1526-4025
pISSN - 1524-1904
DOI - 10.1002/asmb.2566
Subject(s) - predictability , entropy (arrow of time) , closeness , information theory , kullback–leibler divergence , divergence (linguistics) , residual , computer science , joint entropy , mathematics , signature (topology) , statistical physics , algorithm , principle of maximum entropy , statistics , artificial intelligence , physics , mathematical analysis , geometry , linguistics , philosophy , quantum mechanics
Shannon entropy is a useful criterion for measuring the uncertainty (predictability) of lifetimes of engineering systems. In this work, we provide an explicit expression for the entropy of the residual lifetime of a working used system with exactly i failed components at time t , using dynamic signature. We also present additional results on bounds and ordering properties for the proposed entropy. We find an expression for the Jensen‐Shannon (JS) divergence of the residual lifetime of a working used system, and show that the JS divergence of the system is equal to that of its dual. An improved bound for the JS divergence is also obtained. Finally, based on the proposed entropy, we introduce a criterion using which we can prefer a system. This criterion, a distribution‐free measure that only depends on the dynamic signature, ranks systems based on their closeness to extreme systems.