Dynamic behavior of HID-MH lamps when operating at high frequency with a square wave
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Abstract
The dynamic operating characteristics of the equivalent impedance of metal halide lamps, when fed with a high-frequency square wave (10 kHz to 50 kHz), are investigated. Electrical variables such as voltage, current, and power, as well as physical variables such as temperature and luminous intensity, are analyzed in their behavior against variations in the frequency of operation. In addition, a method that allows quantifying the amplitude of the longitudinal acoustic resonance in each frequency of operation of the HID-MH lamps is proposed.
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[2] H. Nishimura, H. Nagase, K. Uchihashi, T. Shiomi, and M. Fukuhara, “A new electronic ballasts for hid lamps,” J. Illum. Eng. Soc., vol. 17, no. 2, pp. 70–76, 1988.
[3] L. Hua, S. Miaosen, J. Yifeng, and Q. Zhaoming, “A novel low- frequency electronic ballast for hid lamps,” Industry Applications, IEEE Transactions, vol. 41, no. 5, pp. 1401–1408, 2005.
[4] G. Lister, “The physics of discharge lamps,” vol. 76, 2004.
[5] W. Kaiser, R. Marques, and A. Correa, “An alternative optical method for acoustic resonance detection in hid lamps,” in Industry Applications
Society Annual Meeting (IAS), 2011, pp. 1–5.
[6] Y. Wang, D. Xu, W. Wang, X. Zhang, and B. Xu, “Electronic ballast for
metal halide lamps using a quasi-resonant inverter with digital control,” Industrial Electronics, IEEE Transactions, vol. 59, no. 4, pp. 1825–1840, 2012.
[7] Television-Composite Analog Video Signal-NTSC for Studio Applica- tions. SMPTE-170M, 1994.
[8] M. Costa, J. Alonso, J. Garcia, J. Cardesin, and M. Rico Secades, “Acoustic resonance characterization of low-wattage metal-halide lamps under low-frequency square-waveform operation,” in Power Electronics, IEEE Transactions, vol. 22, 2007, pp. 735–743.
[9] M. Dalla Costa, “Compensación de resonancias acústicas en lámparas de descarga en halogenuros metálicos por medio de onda cuadrada de baja frecuencia: Caracterización de lámparas y propuesta de nuevas topologías de alimentación,” Ph.D. dissertation, 2008.
[10] D. Van Casteren, M. Hendrix, and J. Duarte, “Controlled hid lamp- ballast interaction for low-frequency square-wave drivers,” Power Elec- tronics, IEEE Transactions, vol. 22, no. 3, pp. 780–788, 2007.
[11] J. Vila Masot and O. Melis, Low frequency square wave electronic ballasts for gas discharge. USA: Patent US 5428268 A, 1995.
[12] C. Hung Liang, M. Chin Sien, Y. Chung Sheng, and H. Chun Kai, “Analysis and implementation of an hpf electronic ballast for hid lamps with lfsw voltage,” Power Electronics, IEEE Transactions, vol. 27, no. 11, pp. 4584–4593, 2012.
[13] Y. Wei and S. Hui, “An analysis into the dimming control and cha- racteristic of discharge lamps,” Power Electronics, IEEE Transactions, vol. 20, no. 6, pp. 1432–1440, 2005.