Application of coupled electro-thermal and physics-of-failure-based analysis to the design of accelerated life tests for power modules

•A reduced-order thermal model coupled with physics-of-failure-based life models.•Study of effects of power and thermal cycling on two main failure mechanisms.•Identify the dominant wear-out mechanism with minimum elapsed time.•Appropriate reliability assessment to predict lifetime under in-service...

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Veröffentlicht in:	Microelectronics and reliability 2014-01, Vol.54 (1), p.172-181
Hauptverfasser:	Musallam, Mahera, Yin, Chunyan, Bailey, Chris, Johnson, C. Mark
Format:	Artikel
Sprache:	eng
Schlagworte:	Applied sciences Bonding Cycles Degradation Design engineering Design. Technologies. Operation analysis. Testing Electrical engineering. Electrical power engineering Electronic equipment and fabrication. Passive components, printed wiring boards, connectics Electronics Exact sciences and technology Failure Failure mechanisms Integrated circuits Modules Power electronics, power supplies Semiconductor electronics. Microelectronics. Optoelectronics. Solid state devices Testing, measurement, noise and reliability Thermal cycling
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container_title	Microelectronics and reliability
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creator	Musallam, Mahera Yin, Chunyan Bailey, Chris Johnson, C. Mark
description	•A reduced-order thermal model coupled with physics-of-failure-based life models.•Study of effects of power and thermal cycling on two main failure mechanisms.•Identify the dominant wear-out mechanism with minimum elapsed time.•Appropriate reliability assessment to predict lifetime under in-service conditions.•Important method for design and qualification tests of power electronic modules. In the reliability theme a central activity is to investigate, characterize and understand the contributory wear-out and overstress mechanisms to meet through-life reliability targets. For power modules, it is critical to understand the response of typical wear-out mechanisms, for example wire-bond lifting and solder degradation, to in-service environmental and load-induced thermal cycling. This paper presents the use of a reduced-order thermal model coupled with physics-of-failure-based life models to quantify the wear-out rates and life consumption for the dominant failure mechanisms under prospective in-service and qualification test conditions. When applied in the design of accelerated life and qualification tests it can be used to design tests that separate the failure mechanisms (e.g. wire-bond and substrate-solder) and provide predictions of conditions that yield a minimum elapsed test time. The combined approach provides a useful tool for reliability assessment and estimation of remaining useful life which can be used at the design stage or in-service. An example case study shows that it is possible to determine the actual power cycling frequency for which failure occurs in the shortest elapsed time. The results demonstrate that bond-wire degradation is the dominant failure mechanism for all power cycling conditions whereas substrate-solder failure dominates for externally applied (ambient or passive) thermal cycling.
doi_str_mv	10.1016/j.microrel.2013.08.017
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This paper presents the use of a reduced-order thermal model coupled with physics-of-failure-based life models to quantify the wear-out rates and life consumption for the dominant failure mechanisms under prospective in-service and qualification test conditions. When applied in the design of accelerated life and qualification tests it can be used to design tests that separate the failure mechanisms (e.g. wire-bond and substrate-solder) and provide predictions of conditions that yield a minimum elapsed test time. The combined approach provides a useful tool for reliability assessment and estimation of remaining useful life which can be used at the design stage or in-service. An example case study shows that it is possible to determine the actual power cycling frequency for which failure occurs in the shortest elapsed time. 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Mark</creatorcontrib><title>Application of coupled electro-thermal and physics-of-failure-based analysis to the design of accelerated life tests for power modules</title><title>Microelectronics and reliability</title><description>•A reduced-order thermal model coupled with physics-of-failure-based life models.•Study of effects of power and thermal cycling on two main failure mechanisms.•Identify the dominant wear-out mechanism with minimum elapsed time.•Appropriate reliability assessment to predict lifetime under in-service conditions.•Important method for design and qualification tests of power electronic modules. In the reliability theme a central activity is to investigate, characterize and understand the contributory wear-out and overstress mechanisms to meet through-life reliability targets. For power modules, it is critical to understand the response of typical wear-out mechanisms, for example wire-bond lifting and solder degradation, to in-service environmental and load-induced thermal cycling. This paper presents the use of a reduced-order thermal model coupled with physics-of-failure-based life models to quantify the wear-out rates and life consumption for the dominant failure mechanisms under prospective in-service and qualification test conditions. When applied in the design of accelerated life and qualification tests it can be used to design tests that separate the failure mechanisms (e.g. wire-bond and substrate-solder) and provide predictions of conditions that yield a minimum elapsed test time. The combined approach provides a useful tool for reliability assessment and estimation of remaining useful life which can be used at the design stage or in-service. 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Passive components, printed wiring boards, connectics</subject><subject>Electronics</subject><subject>Exact sciences and technology</subject><subject>Failure</subject><subject>Failure mechanisms</subject><subject>Integrated circuits</subject><subject>Modules</subject><subject>Power electronics, power supplies</subject><subject>Semiconductor electronics. Microelectronics. Optoelectronics. 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Mark</au><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>Application of coupled electro-thermal and physics-of-failure-based analysis to the design of accelerated life tests for power modules</atitle><jtitle>Microelectronics and reliability</jtitle><date>2014-01</date><risdate>2014</risdate><volume>54</volume><issue>1</issue><spage>172</spage><epage>181</epage><pages>172-181</pages><issn>0026-2714</issn><eissn>1872-941X</eissn><coden>MCRLAS</coden><abstract>•A reduced-order thermal model coupled with physics-of-failure-based life models.•Study of effects of power and thermal cycling on two main failure mechanisms.•Identify the dominant wear-out mechanism with minimum elapsed time.•Appropriate reliability assessment to predict lifetime under in-service conditions.•Important method for design and qualification tests of power electronic modules. 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source	ScienceDirect Journals (5 years ago - present)
subjects	Applied sciences Bonding Cycles Degradation Design engineering Design. Technologies. Operation analysis. Testing Electrical engineering. Electrical power engineering Electronic equipment and fabrication. Passive components, printed wiring boards, connectics Electronics Exact sciences and technology Failure Failure mechanisms Integrated circuits Modules Power electronics, power supplies Semiconductor electronics. Microelectronics. Optoelectronics. Solid state devices Testing, measurement, noise and reliability Thermal cycling
title	Application of coupled electro-thermal and physics-of-failure-based analysis to the design of accelerated life tests for power modules
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