LIFETIME PREDICTION OF SINGLE-STAGE LED DRIVER CIRCUIT USING BAYESIAN BELIEF NETWORK

Lifetime prediction of LED driver using Bayesian Belief Network

Authors

  • SRIDHAR MAKKAPATI REC Laboratory, Department of EEE, Sri Sivasubramaniya Nadar College of Engineering, Chennai, India Author
  • SEYEZHAI RAMALINGAM REC Laboratory, Department of EEE, Sri Sivasubramaniya Nadar College of Engineering, Chennai India Author

DOI:

https://doi.org/10.59277/RRST-EE.2023.4.5

Keywords:

Light-emitting diode (LED), Single-ended primary inductor converter, Parallel ripple cancellation circuit, Bayesian belief network (BBN), Electrolytic capacitor (EC), Mean time to failure (MTF)

Abstract

In light-emitting diode (LED) lighting, the driver commands the lifetime and the LED bulb. It is essential to predict the driver's lifetime during its design stage. This paper proposes a viable method to predict the lifetime of the LED driver based on its failure rate. A novel single-ended primary inductor converter (SEPIC) integrated parallel ripple cancellation circuit (PRC) topology of 30 W is considered to estimate the lifetime of the driver circuit. The failure rate model is regarded as a base to predict the lifetime of LED drivers using Bayesian belief network (BBN) analysis. The weakest links are the prime components to estimate the lifetime, and they are active devices and capacitors employed in the driver circuit. The output capacitor is considered a degree of importance as per the existing literature, and the proposed course has been designed without using any electrolytic capacitor (EC) to enhance the reliability of the driver circuit. This approach ensures an effective way to access the mean time to failure (MTTF) or the lifetime of the LED driver in a lucrative manner.

References

(1) C.C. Raicu, G.C. Seritan, B. Enache, 48 V Network Adoption for Automotive Lighting Systems, Rev. Roum. Sci. Techn. –Électrotechn. Et Énerg, 66, 4, pp. 231–236 (2021)

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

(3) M. Shoyama, T Kurachi, T Ninomiya, Ripple current analysis of an electrolytic capacitor in power factor correctors, Electronics and Communications in Japan (Part II: Electronics), 79, 4, pp. 93–101 (1996).

(4) T.H. Van, T.L. Van, T.M.N. Thi, M.Q. Duong, G.N. Sava, Improving the output of dc-dc converter by phase shift full bridge applied to renewable energy, Rev. Roum. Sci. Techn. –Électrotechn. Et Énerg, 66, 3, pp.175–180, (2021).

(5) L. Gu, X. Ruan, M. Xu, K. Yao, Means of eliminating electrolytic capacitor in ac/dc power supplies for LED lightings, IEEE Transactions on Power Electronics, 24, 5, pp. 1399–1408 (2009).

(6) X. Ruan, B. Wang, K. Yao, S. Wang, Optimum Injected Current Harmonics to Minimize Peak-to-Average Ratio of LED Current for Electrolytic Capacitor-Less AC–DC Drivers, IEEE Transactions on Power Electronics, 26, 7, pp. 1820–1825 (2010).

(7) S. Wang, X. Ruan, K. Yao, S. -C. Tan, Y. Yang, Z. Ye, A flicker-free electrolytic capacitor-less ac–dc LED driver, IEEE Trans. on Power Electronics, 27, 11, pp. 4540–4548 (2012).

(8) L. Davis, M. Hansen, Lumen and Chromaticity Maintenance Behavior of Light-Emitting Diode (LED) Packages Based on LM-80 Data, Office of Scientific and Technical Information (OSTI) (2020).

(9) G.K. Hobbs, H. Hass, Accelerated reliability engineering, Hobbs Engineering Corporation, Westminster, CO. (2005).

(10) L. Yunfei, X. Haiping, Y. Zengquan, L. Jinhua, Developing an accelerated life test method for LED driver and failure analysis, IECON 2017-43rd Annual Conference of the IEEE Industrial Electronics Society, pp. 5039–5042 (2017).

(11) A.N. Padmasali, S.G. Kini, A novel measure to analyse the reliability of LED luminaires, Lighting Res. & Technol., 51, 7, pp. 1063–1076 (2019).

(12) B. Sun, X. Fan, L. Li, H. Ye, W. van Driel, G. Zhang, A reliability prediction for integrated LED lamp with electrolytic capacitor-free driver, IEEE Trans. on Components, Packaging and Manufacturing Technology, 7, 7, pp. 1081–1088 (2017).

(13) S. Pal, B. Singh, A. Shrivastava, Quasi‐constant bus voltage CrCM boost PFC fed LLC resonant converter in high power LED lighting systems, International Journal of Circuit Theory and Applications, 49, 2, pp.1583–1598 (2021).

(14) H. Zhang, Reliability and lifetime prediction of LED drivers, 14th China International Forum on Solid State Lighting: IEEE-International Forum on Wide Bandgap Semiconductors China, pp. 24-27 (2017).

(15) H. Zhang, A viable non-testing method to predict the lifetime of LED drivers, IEEE Journal of Emerging and Selected Topics in Power Electronics, 6, 3, pp.1246-1251 (2018).

(16) S. Lan, C.M. Tan, K. Wu, Reliability study of LED driver–A case study of black box testing, Microelectronics Reliability, 52, 9-10, pp.1940-1944, (2012).

(17) H. Liao, E.A. Elsayed, Reliability inference for field conditions from accelerated degradation testing, Naval Research Logistics (NRL), 53, 6, pp. 576–587 (2016).

(18) M. Meneghini, M. Dal Lago, N. Trivellin, G. Meneghesso, E. Zanoni, Degradation mechanisms of high-power LEDs for lighting applications: An Overview, IEEE Transactions on Industry Applications, 50, 1, pp.78–85 (2014).

(19) K.C. Yung, B. Sun, X. Jiang, Prognostics-based qualification of high-power white LEDs using Lévy process approach, Mechanical Systems and Signal Processing, 82, pp. 206–216 (2017).

(20) E. Ruijters, M.Stoelinga, Fault tree analysis: A survey of the state-of-the-art in modeling, analysis and tools, Computer science review, 15, pp. 29–62 (2015).

(21) B. Cai, X.Kong, Y. Liu, J. Lin, X. Yuan, H. Xu, R. Ji, Application of Bayesian networks in reliability evaluation. IEEE Transactions on Industrial Informatics, 15, 4, pp. 2146–2157 (2018).

(22) D. Zhu, Y. Jiang, Thruster fault diagnosis in autonomous underwater vehicle based on Bayesian network, Int. Conf. on Electrical, Communication, and Computer Engineering (ICECCE), pp. 1–5 (2021).

(23) ***MIL-HDBK-217F, Military Handbook: Reliability Prediction of Electronic Equipment, Department of Defense, Washington, DC (1992).

(24) D. Ziane, A. Azib, A. Oubelaid, N. Taib, T. Rekioua, D. Rekioua, Proposed power factor correction circuit based on the single-ended primary-inductor converter controlled by sliding mode control strategy used in an electric vehicle charging station, Rev. Roum. Sci. Techn. –Électrotechn. Et Énerg, 67, 3, pp. 241–245 (2022).

(25) S. Makkapati, S. Ramalingam, Design and Implementation of Single Stage SEPIC Integrated Parallel Ripple Cancellation Method for LED Lighting, Advances in Electrical and Computer Engineering, 22, 4, pp. 39–46 (2022).

(26) J.L. Quigley, U.B. Kjaerulff, A.L. Madsen, Bayesian networks and influence diagrams: a guide to construction and analysis, J.of the American Statistical Association, 104 (2009).

Downloads

Published

23.12.2023

Issue

Vol. 68 No. 4 (2023): RRST-EE

Section

Électrotechnique et électroénergétique | Electrical and Power Engineering

License

Copyright (c) 2023 REVUE ROUMAINE DES SCIENCES TECHNIQUES — SÉRIE ÉLECTROTECHNIQUE ET ÉNERGÉTIQUE

Creative Commons License

This work is licensed under a Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 International License.

How to Cite

LIFETIME PREDICTION OF SINGLE-STAGE LED DRIVER CIRCUIT USING BAYESIAN BELIEF NETWORK: Lifetime prediction of LED driver using Bayesian Belief Network. (2023). REVUE ROUMAINE DES SCIENCES TECHNIQUES — SÉRIE ÉLECTROTECHNIQUE ET ÉNERGÉTIQUE, 68(4), 351-356. https://doi.org/10.59277/RRST-EE.2023.4.5