Estimate the Meaning-Time-To-Failure of LED driver using Numerical simulation

  • Affiliations:

    1 Hanoi University of Mining and Geology, Hanoi, Vietnam
    2 Advanced Technology Joint Stock Company, Hanoi, Vietnam

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  • Received: 25th-July-2021
  • Revised: 26th-Oct-2021
  • Accepted: 25th-Nov-2021
  • Online: 31st-Dec-2021
Pages: 64 - 71
Views: 2440
Downloads: 979
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Abstract:

The Meaning-Time-To-Failure (MTTP), also known as Electromigration Analysis is an estimation of product life. Light-Emitting Diodes (LEDs) are usually driven by constant current switched-mode power supplies, which are invented early than LEDs for lighting applications. While LEDs themselves are extremely reliable and have a long lifetime, the electronic LED drivers in experiment usually fail due to overheating causing Printed Circuit Boards (PCBs) explosion, inability provide current/voltage input to the LEDs over their whole lifetime. This paper proposes a numerical simulation method to predict fault location on PCB of LED driver based on 2-way coupling electro-thermal multiphysic analysis, then applies the analytic models to calculate the time to failure of the points on PCB of LED drivers. The procedures can be applied to assist managers in assessing risk and making LED-based lighting system reliability decisions.

How to Cite
Nguyen, S.Tien and Pham, A.Dinh 2021. Estimate the Meaning-Time-To-Failure of LED driver using Numerical simulation. Journal of Mining and Earth Sciences. 62, 6 (Dec, 2021), 64-71. DOI:https://doi.org/10.46326/JMES.2021.62(6).09.
References

J. Huang, D. S. Golubovic, S. Koh, D. Yang, X. Li, X. J. Fan, and G. Q. Zhang, (2015). Degradation mechanisms of mid-power white-light LEDs under high-temperature-humidity conditions. IEEE Transactions on Device and Materials Reliability 15(2), 220-228.

F. Haghighi and S. J. Bae, (2015). Reliatbility estimation from linear degradation and failure time data with competing risks under a step-stress accelerated degradation test. IEEE Transactions on Reliability 64(3), 960-971.

C. Quian, X. J. Fan, C. Yuan, and G. Q. Zhang, (2016). An accelerated test method of luminous flux depreciation for LED luminaires and lamps. 

Reliability Engineering and System Safety 147, 84-92.

R. Wu, F. Blaabejerg, H. Wang, and M. Liserre, (2013). Overview of catastrophic failures of freewheeling diodes in power electronic circuits. Microelectronics Reliability 53(9-11), 1788-1792.

S. Lan, C. M. Tan, and K. Wu., (2014). Methodology of reliability enhancement for high power LED driver. Microelectronics Reliability 53(6-7), 1150-1159.

Black, J. R., (1969). Electromigration – A Brief Survey and Some Recent Results. IEEE Transactions on Electron Devices. 16(4), 338-347.

R. L. de Orio, H. Ceric, (2010). Physically based models of electromigration: From Black’s equation to modern TCAD models. Microelectronics Reliability journal

W. D. van Driel and X. J, Fan, (2012). Solid state lighting reliability: components to system. Springer. New York, 628 pages 

Pradeep Lall, Peter Sakalaukus, and Lynn Davis, (2015). Reliability and Failure Modes of Solid-State Lighting Electrical Drivers Subjected to Accelerated Aging. IEEE. Translations and content mining are permitted for academic research only. IEEE Access (3), 2169-3536

Michael Riebling, Philips Hadco and OptoElectronix David Szombatfalvy, (2011). LED Luminaire Lifetime: Recommendations for Testing and Reporting Solid-State Lighting Product Quality Initiative Third. Next Generation Lighting Industry Alliance (NGLIA) formed SSL Quality Advocates and a Reliability and Lifetime Working Group, 35 pages.

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