Optimizing system design under degrading failure agents

Avner Engel; Ron S. Kenett; Shalom Shachar; Yoram Reich

doi:https://doi.org/10.1109/SMRLO.2016.26

Optimizing system design under degrading failure agents

Avner Engel, Ron S. Kenett, Shalom Shachar, Yoram Reich

School of Mechanical Engineering

Tel Aviv University

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

Abstract

Taguchi's quality loss function defines a quadratic relationship between deviations from a target values and loss to society. Under this approach, targets of system performance indicators, are set to minimize this loss. Traditionally, robust design engineers make the implicit assumption that failure agents affect systems' technical parameters stochastically, under steady state. Consequently, robust design strategy seeks to minimize societal loss by setting each technical parameter as close as possible to the lowest value on the loss function, usually the mid-point between the lower and upper specification limits. However, on closer examination, it can be demonstrated that many failure agents affect systems (e.g., electronic components, Mechanical elements, Software pieces) in a predictable, dynamic direction and rate. The authors denote such agents «Degrading Failure Agents». The paper describes an optimized design strategy accounting for degrading failure agents. This is done by setting the operating points of technical parameters to counteract the effects of such failure agents. The approach is demonstrated with a cardiac pacemaker case study that considers several types of degradation models including joint models and Weibull bathtub distributions.

Original language	English
Title of host publication	Proceedings - 2nd International Symposium on Stochastic Models in Reliability Engineering, Life Science, and Operations Management, SMRLO 2016
Editors	Anatoly Lisnianski, Ilia Frenkel
Publisher	Institute of Electrical and Electronics Engineers Inc.
Pages	95-103
Number of pages	9
ISBN (Electronic)	9781467399418
DOIs	https://doi.org/10.1109/SMRLO.2016.26
State	Published - 11 Mar 2016
Event	2nd International Symposium on Stochastic Models in Reliability Engineering, Life Science, and Operations Management, SMRLO 2016 - Beer Sheva, Israel Duration: 15 Feb 2016 → 18 Feb 2016

Publication series

Name	Proceedings - 2nd International Symposium on Stochastic Models in Reliability Engineering, Life Science, and Operations Management, SMRLO 2016

Conference

Conference	2nd International Symposium on Stochastic Models in Reliability Engineering, Life Science, and Operations Management, SMRLO 2016
Country/Territory	Israel
City	Beer Sheva
Period	15/02/16 → 18/02/16

Keywords

Cardiac Pacemaker
Degradation Models
Degrading Failure Agents
Robust Design
Taguchi

All Science Journal Classification (ASJC) codes

Safety, Risk, Reliability and Quality
Modelling and Simulation
Statistics and Probability
Agricultural and Biological Sciences (miscellaneous)
Strategy and Management

Access to Document

https://doi.org/10.1109/SMRLO.2016.26

Cite this

Engel, A., Kenett, R. S., Shachar, S., & Reich, Y. (2016). Optimizing system design under degrading failure agents. In A. Lisnianski, & I. Frenkel (Eds.), Proceedings - 2nd International Symposium on Stochastic Models in Reliability Engineering, Life Science, and Operations Management, SMRLO 2016 (pp. 95-103). Article 7433101 (Proceedings - 2nd International Symposium on Stochastic Models in Reliability Engineering, Life Science, and Operations Management, SMRLO 2016). Institute of Electrical and Electronics Engineers Inc.. https://doi.org/10.1109/SMRLO.2016.26

Engel, Avner ; Kenett, Ron S. ; Shachar, Shalom et al. / Optimizing system design under degrading failure agents. Proceedings - 2nd International Symposium on Stochastic Models in Reliability Engineering, Life Science, and Operations Management, SMRLO 2016. editor / Anatoly Lisnianski ; Ilia Frenkel. Institute of Electrical and Electronics Engineers Inc., 2016. pp. 95-103 (Proceedings - 2nd International Symposium on Stochastic Models in Reliability Engineering, Life Science, and Operations Management, SMRLO 2016).

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abstract = "Taguchi's quality loss function defines a quadratic relationship between deviations from a target values and loss to society. Under this approach, targets of system performance indicators, are set to minimize this loss. Traditionally, robust design engineers make the implicit assumption that failure agents affect systems' technical parameters stochastically, under steady state. Consequently, robust design strategy seeks to minimize societal loss by setting each technical parameter as close as possible to the lowest value on the loss function, usually the mid-point between the lower and upper specification limits. However, on closer examination, it can be demonstrated that many failure agents affect systems (e.g., electronic components, Mechanical elements, Software pieces) in a predictable, dynamic direction and rate. The authors denote such agents «Degrading Failure Agents». The paper describes an optimized design strategy accounting for degrading failure agents. This is done by setting the operating points of technical parameters to counteract the effects of such failure agents. The approach is demonstrated with a cardiac pacemaker case study that considers several types of degradation models including joint models and Weibull bathtub distributions.",

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Engel, A, Kenett, RS, Shachar, S & Reich, Y 2016, Optimizing system design under degrading failure agents. in A Lisnianski & I Frenkel (eds), Proceedings - 2nd International Symposium on Stochastic Models in Reliability Engineering, Life Science, and Operations Management, SMRLO 2016., 7433101, Proceedings - 2nd International Symposium on Stochastic Models in Reliability Engineering, Life Science, and Operations Management, SMRLO 2016, Institute of Electrical and Electronics Engineers Inc., pp. 95-103, 2nd International Symposium on Stochastic Models in Reliability Engineering, Life Science, and Operations Management, SMRLO 2016, Beer Sheva, Israel, 15/02/16. https://doi.org/10.1109/SMRLO.2016.26

Optimizing system design under degrading failure agents. / Engel, Avner; Kenett, Ron S.; Shachar, Shalom et al.
Proceedings - 2nd International Symposium on Stochastic Models in Reliability Engineering, Life Science, and Operations Management, SMRLO 2016. ed. / Anatoly Lisnianski; Ilia Frenkel. Institute of Electrical and Electronics Engineers Inc., 2016. p. 95-103 7433101 (Proceedings - 2nd International Symposium on Stochastic Models in Reliability Engineering, Life Science, and Operations Management, SMRLO 2016).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

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N2 - Taguchi's quality loss function defines a quadratic relationship between deviations from a target values and loss to society. Under this approach, targets of system performance indicators, are set to minimize this loss. Traditionally, robust design engineers make the implicit assumption that failure agents affect systems' technical parameters stochastically, under steady state. Consequently, robust design strategy seeks to minimize societal loss by setting each technical parameter as close as possible to the lowest value on the loss function, usually the mid-point between the lower and upper specification limits. However, on closer examination, it can be demonstrated that many failure agents affect systems (e.g., electronic components, Mechanical elements, Software pieces) in a predictable, dynamic direction and rate. The authors denote such agents «Degrading Failure Agents». The paper describes an optimized design strategy accounting for degrading failure agents. This is done by setting the operating points of technical parameters to counteract the effects of such failure agents. The approach is demonstrated with a cardiac pacemaker case study that considers several types of degradation models including joint models and Weibull bathtub distributions.

AB - Taguchi's quality loss function defines a quadratic relationship between deviations from a target values and loss to society. Under this approach, targets of system performance indicators, are set to minimize this loss. Traditionally, robust design engineers make the implicit assumption that failure agents affect systems' technical parameters stochastically, under steady state. Consequently, robust design strategy seeks to minimize societal loss by setting each technical parameter as close as possible to the lowest value on the loss function, usually the mid-point between the lower and upper specification limits. However, on closer examination, it can be demonstrated that many failure agents affect systems (e.g., electronic components, Mechanical elements, Software pieces) in a predictable, dynamic direction and rate. The authors denote such agents «Degrading Failure Agents». The paper describes an optimized design strategy accounting for degrading failure agents. This is done by setting the operating points of technical parameters to counteract the effects of such failure agents. The approach is demonstrated with a cardiac pacemaker case study that considers several types of degradation models including joint models and Weibull bathtub distributions.

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M3 - منشور من مؤتمر

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Engel A, Kenett RS, Shachar S, Reich Y. Optimizing system design under degrading failure agents. In Lisnianski A, Frenkel I, editors, Proceedings - 2nd International Symposium on Stochastic Models in Reliability Engineering, Life Science, and Operations Management, SMRLO 2016. Institute of Electrical and Electronics Engineers Inc. 2016. p. 95-103. 7433101. (Proceedings - 2nd International Symposium on Stochastic Models in Reliability Engineering, Life Science, and Operations Management, SMRLO 2016). doi: https://doi.org/10.1109/SMRLO.2016.26

Optimizing system design under degrading failure agents

Abstract

Publication series

Conference

Keywords

All Science Journal Classification (ASJC) codes

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