Reliability Modeling for Humidity Sensors Subject to Multiple Dependent Competing Failure Processes with Self-Recovery

Recent developments in humidity sensors have heightened the need for reliability. Seeing as many products such as humidity sensors experience multiple dependent competing failure processes (MDCFPs) with self-recovery, this paper proposes a new general reliability model. Previous research into MDCFPs...

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Published inSensors (Basel, Switzerland) Vol. 18; no. 8; p. 2714
Main Authors Qi, Jia, Zhou, Zhen, Niu, Chenchen, Wang, Chunyu, Wu, Juan
Format Journal Article
LanguageEnglish
Published Switzerland MDPI AG 18.08.2018
MDPI
Subjects
dependent competing failure
Failure
Humidity
humidity sensor
random shocks
reliability model
self-recovery
Sensors
United States > US
China
self-recovery
random shocks
humidity sensor
dependent competing failure
reliability model
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Abstract Recent developments in humidity sensors have heightened the need for reliability. Seeing as many products such as humidity sensors experience multiple dependent competing failure processes (MDCFPs) with self-recovery, this paper proposes a new general reliability model. Previous research into MDCFPs has primarily focused on the processes of degradation and random shocks, which are appropriate for most products. However, the existing reliability models for MDCFPs cannot fully characterize the failure processes of products such as humidity sensors with significant self-recovery, leading to an underestimation of reliability. In this paper, the effect of self-recovery on degradation was analyzed using a conditional probability. A reliability model for soft failure with self-recovery was obtained. Then, combined with the model of hard failure due to random shocks, a general reliability model with self-recovery was established. Finally, reliability tests of the humidity sensors were presented to verify the proposed reliability model. Reliability modeling for products subject to MDCFPs with considering self-recovery can provide a better understanding of the mechanism of failure and offer an alternative method to predict the reliability of products.
AbstractList Recent developments in humidity sensors have heightened the need for reliability. Seeing as many products such as humidity sensors experience multiple dependent competing failure processes (MDCFPs) with self-recovery, this paper proposes a new general reliability model. Previous research into MDCFPs has primarily focused on the processes of degradation and random shocks, which are appropriate for most products. However, the existing reliability models for MDCFPs cannot fully characterize the failure processes of products such as humidity sensors with significant self-recovery, leading to an underestimation of reliability. In this paper, the effect of self-recovery on degradation was analyzed using a conditional probability. A reliability model for soft failure with self-recovery was obtained. Then, combined with the model of hard failure due to random shocks, a general reliability model with self-recovery was established. Finally, reliability tests of the humidity sensors were presented to verify the proposed reliability model. Reliability modeling for products subject to MDCFPs with considering self-recovery can provide a better understanding of the mechanism of failure and offer an alternative method to predict the reliability of products.
Recent developments in humidity sensors have heightened the need for reliability. Seeing as many products such as humidity sensors experience multiple dependent competing failure processes (MDCFPs) with self-recovery, this paper proposes a new general reliability model. Previous research into MDCFPs has primarily focused on the processes of degradation and random shocks, which are appropriate for most products. However, the existing reliability models for MDCFPs cannot fully characterize the failure processes of products such as humidity sensors with significant self-recovery, leading to an underestimation of reliability. In this paper, the effect of self-recovery on degradation was analyzed using a conditional probability. A reliability model for soft failure with self-recovery was obtained. Then, combined with the model of hard failure due to random shocks, a general reliability model with self-recovery was established. Finally, reliability tests of the humidity sensors were presented to verify the proposed reliability model. Reliability modeling for products subject to MDCFPs with considering self-recovery can provide a better understanding of the mechanism of failure and offer an alternative method to predict the reliability of products.Recent developments in humidity sensors have heightened the need for reliability. Seeing as many products such as humidity sensors experience multiple dependent competing failure processes (MDCFPs) with self-recovery, this paper proposes a new general reliability model. Previous research into MDCFPs has primarily focused on the processes of degradation and random shocks, which are appropriate for most products. However, the existing reliability models for MDCFPs cannot fully characterize the failure processes of products such as humidity sensors with significant self-recovery, leading to an underestimation of reliability. In this paper, the effect of self-recovery on degradation was analyzed using a conditional probability. A reliability model for soft failure with self-recovery was obtained. Then, combined with the model of hard failure due to random shocks, a general reliability model with self-recovery was established. Finally, reliability tests of the humidity sensors were presented to verify the proposed reliability model. Reliability modeling for products subject to MDCFPs with considering self-recovery can provide a better understanding of the mechanism of failure and offer an alternative method to predict the reliability of products.
Author Wu, Juan
Zhou, Zhen
Niu, Chenchen
Qi, Jia
Wang, Chunyu
AuthorAffiliation 2 College of Precision Instruments and Opto-electronics Engineering, Tianjin University, Tianjin 300072, China; taozi_xixi@163.com
1 School of Measurement and Communication Engineering, Harbin University of Science and Technology, Harbin 150080, China; qjia89@hrbust.edu.cn (J.Q.); samueland@126.com (C.N.); wangchunyu230281@163.com (C.W.)
AuthorAffiliation_xml – name: 2 College of Precision Instruments and Opto-electronics Engineering, Tianjin University, Tianjin 300072, China; taozi_xixi@163.com
– name: 1 School of Measurement and Communication Engineering, Harbin University of Science and Technology, Harbin 150080, China; qjia89@hrbust.edu.cn (J.Q.); samueland@126.com (C.N.); wangchunyu230281@163.com (C.W.)
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BackLink https://www.ncbi.nlm.nih.gov/pubmed/30126168$$D View this record in MEDLINE/PubMed
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Keywords self-recovery
random shocks
humidity sensor
dependent competing failure
reliability model
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SSID ssj0023338
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Snippet Recent developments in humidity sensors have heightened the need for reliability. Seeing as many products such as humidity sensors experience multiple...
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SubjectTerms dependent competing failure
Failure
Humidity
humidity sensor
random shocks
reliability model
self-recovery
Sensors
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Title Reliability Modeling for Humidity Sensors Subject to Multiple Dependent Competing Failure Processes with Self-Recovery
URI https://www.ncbi.nlm.nih.gov/pubmed/30126168
https://www.proquest.com/docview/2108870887
https://www.proquest.com/docview/2126389193
https://www.proquest.com/docview/2091236791
https://pubmed.ncbi.nlm.nih.gov/PMC6111381
https://doaj.org/article/29c035319cba4c818299305ce39b3519
Volume 18
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