Application of multi-output Gaussian process regression for remaining useful life prediction of light emitting diodes

Application of multi-output Gaussian process regression for remaining useful life prediction of light emitting diodes

Light-emitting diodes (LEDs) are the preferred technology today when it comes to lighting both for indoor and outdoor applications, predominantly due to their high efficiency, environmental resilience and prolonged lifetime. Given their widespread use, there is a need to quickly qualify them and acc...

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Bibliographic Details
Published in:Microelectronics and reliability Vol. 88-90; pp. 80 - 84
Main Authors: Duong, Pham Luu Trung, Park, Hyunseok, Raghavan, Nagarajan
Format: Journal Article
Language:English
Published: Elsevier Ltd 01-09-2018
Subjects:
Gaussian process regression
Light emitting diode
Prognostic health management
Remaining useful life
Gaussian process regression
Prognostic health management
Remaining useful life
Light emitting diode
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Summary:Light-emitting diodes (LEDs) are the preferred technology today when it comes to lighting both for indoor and outdoor applications, predominantly due to their high efficiency, environmental resilience and prolonged lifetime. Given their widespread use, there is a need to quickly qualify them and accurately predict the reliability of these devices. Due to their inherently long operational life, most LED reliability studies involve the use of degradation tests and application of filter-based prognostic techniques for dynamic update of degradation model parameters and estimation of the remaining useful life (RUL). Although they are in general very effective, the main drawback is the need for a specific state-space model that describes the degradation. In many cases, LED degradation trends are affected by a multitude of unknown factors such as unidentified failure modes, varying operational conditions, process and measurement variance, and environmental fluctuations. These variable factors that are hard to control tend to complicate the selection of a suitable state-space model and in some cases; there may not be a single model that could be used for the entire lifespan of the device. If the degradation patterns of LEDs under test deviate from the state space models, the resulting predictions will be inaccurate. This paper introduces a prognostics-based qualification method using a multi-output Gaussian process regression (MO-GPR) and applies it to RUL prediction of high-power LED devices. The main idea here is to use MO-GPR to learn the correlation between similar degradation patterns from multiple similar components under test and thereby, bypass the need for a specific state space model using available data of past units tested to failure. •Multi-output Gaussian process regression (MO-GPR) approach is presented for remaining useful life prediction of LEDs.•The proposed algorithm is useful for RUL estimation when degradation trends do not follow a definite monotonic relationship.•The method leverages on existing run-to-failure data sets for pattern learning of the degradation traces.•Comparison of MO-GPR with single output GPR and standard particle filter reveals improved accuracy of RUL prediction.
ISSN:0026-2714
1872-941X
DOI:10.1016/j.microrel.2018.07.106