A Novel LED Photo-Electro-Thermal Model with Simplified Variables

[1] [1] M. Schmid, D. Kuebrich, M. Weiland et al.. Evaluation on the efficiency of power LEDs driven with currents typical to switch mode power supplies[C]. Proceedings of IEEE Industry Applications Conference, 42nd IAS Annual Meeting, 2007. 1135～1140

[2] [2] J. Garcia, D. G. Lamar, M. A. Costa et al.. An estimator of luminous flux for enhanced control of high brightness LEDs [C]. Proceedings of IEEE PESC, 2008. 1852～1856

[3] [3] Lei Ruirui, Lü Yijun, Gao Yulin et al.. Measurement of the thermo-optic parameters of power LED on pulse current [J]. Acta Optica Sinica, 2009, 29(s2): 342～345

[4] [4] M. R. Krames, B. Oleg Shchekin, R. Mueller-Mach et al.. Status and future of high-power light-emitting diodes for solid-state lighting [J]. J. Display Technol., 2007, 3(7): 160～175

[5] [5] Liu Pei, Chai Guangyue, Guo Lunchun et al.. Optoelectric analysis of LED based on different thermal structure [J]. China Illuminating Engineering Journal, 2011, 22(6): 46～50

[6] [6] Chen Huanting, Lü Yijun, Chen Zhong et al.. Analysis of thermal spreading boards for high power AlGaInP red LEDs [J]. Acta Optica Sinica, 2009, 29(3): 805～810

[7] [7] C. Biber. LED light emission as a function of thermal conditions [C]. Proceedings of IEEE Semicond. Thermal Meas. Manag., 2008. 180～184

[8] [8] Chen Yingliang, Lü Yijun, Gao Yulin et al.. Photoelectric properties of alternating-current light-emitting diodes [J]. Acta Optica Sinica, 2010, 30(12): 3586～3591

[9] [9] S. Y. R. Hui, Y. X. Qin. A general photo-electro-thermal theory for light-emitting-diode (LED) systems [J]. IEEE Trans. Power Electronics, 2009, 24(8): 1967～1976

[10] [10] X. Tao, Y. R. S. Hui. A general photo-electro-temporal thermal theory for light-emitting-diode (LED) systems [C]. Proceedings of IEEE Energy Conversion Congress and Exposition (ECCE), 2010. 184～191

[11] [11] J. M. Zhou, W. Yan．Experimental investigation on the performance characteristics of white LEDs used in illumination application [C]. Proceedings of IEEE PESC, 2007. 1436～1440

[12] [12] Cheng Ting. Investigation on Thermal Charaeteristics of High Power White LEDs Devices [D]. Wuhan: Huazhong University of Science and Technology, 2009

[13] [13] T. Zahner. Thermal management and thermal resistance of high power LEDs [C]. Proceedings of IEEE 13th Int. Workshop Thermal Investigation ICs Syst., 2007. 195～195

[14] [14] Yi Zechun, Xiong Wang, Wang Li et al.. Thermal analysis of multi-chip package of high power LEDs [J]. Semiconductor Optoelectronics, 2011, 32(3): 320～324

[15] [15] Yaxiao Qin, Deyan Lin, S. Y. (Ron) Hui. A simple method for comparative study on the thermal performance of LEDs and fluorescent lamps [J]. IEEE Trans. Power Electronics, 2009, 24(7): 1811～1818

[16] [16] Huanting T. Chen, Xuehui H. Tao, S. Y. Ron Hui. Estimation of optical power and heat-dissipation coefficient for the photo-electro-thermal theory for LED systems [J]. IEEE Trans. Power Electronics, 2012, 27(4): 2176～2183

[17] [17] A. Poppe. A step forward in multi-domain modeling of power LEDs [C]. Proceedings of IEEE Semicond. Thermal Meas. Manag. Symp., 2012. 325～330

[18] [18] N. Catalin, S. Paul, R. Marius. Electro-thermal modeling of power LED using SPICE circuit solver [C]. Proceedings of IEEE 35th International Spring Seminar on Electronics Technology (ISSE), 2012. 329～334

[19] [19] P. Baureis. Compact modeling of electrical, thermal and optical LED behaviov [C]. Proceedings of IEEE 35th European LED Behavior Solid-State Device Research Conference, 2005. 145～148