Browse > Article
http://dx.doi.org/10.5302/J.ICROS.2015.15.0112

Characteristics of Boost Active Power Factor Correction Converter  

Jang, Jun-Young (School of Computer, Semyung University)
Lin, Chi-Ho (School of Computer, Semyung University)
Publication Information
Journal of Institute of Control, Robotics and Systems / v.21, no.12, 2015 , pp. 1152-1159 More about this Journal
Abstract
Switching power supply systems are widely used in many industrial fields. Power factor correction (PFC) circuits have a tendency to be applied in new power supply designs. The PFC circuit with a boost converter using an input power source is studied in this paper. In a boost PFC circuit, there are two feedback control loops: a current feedback loop and a voltage feedback loop. In this paper, the regulation performance gained by using the output voltage and compensator to improve the transient response presented at the continuous conduction mode (CCM) of the boost PFC circuit is analyzed. The validity of the designed boost PFC circuit is confirmed by both MATLAB simulation and experimental results.
Keywords
CCM; DCM; GM; PFC; PM; voltage control loop gain;
Citations & Related Records
Times Cited By KSCI : 2  (Citation Analysis)
연도 인용수 순위
1 J. Sebastian, M. J. Aureguizar, and J. Uceda, "An overview of power factor correction in single phase off-line power supply systems," Industrial Electronics, Control and Instrumentation, IECON'94, 20th International Conference on, vol. 3, IEEE, 1994.
2 M. N. Abdullah, "Design of a single phase unity power factor switch mode power supply (SMPS) with active power factor correction," [TK7881]. 15. N335 2008 frb], Diss. Universiti Sains Malaysia, Sep. 2008.
3 J. Zhang, M. M. Jovanovic, and F. C. Lee, "Comparison between CCM single-stage and two-stage boost PFC converters," In IEEE APEC, vol. 99, pp. 335-341, Mar. 1994.
4 C. Zhou and M. M. Jovanovic, "Design trade-offs in continuous current mode controlled boost power factor correction circuits," In High Frequency Power Conversion Conference, pp. 209-220, May 1992.
5 B. Choi, S.-S. Hong, and H. Park, "Modeling and small-signal analysis of controlled on-time boost power factor correction circuit," IEEE Transactions on Industrial Electronics, vol. 48, no. 1, Feb. 2001.
6 L. Dixon, "Average current mode control of switching power supplies," Unitrode Corporation, Application U-140, pp. 3-356-3-369, 1999.
7 P. Cooke, "Modeling average current mode control," Unitrode Integrated Circuits Corporation, pp. 256-262, 2000.
8 P. C. Todd, "UC3854 controlled power factor correction circuit design," Unitrode Corporation, Application note U-134, pp. 3268-3289, 1997.
9 B. Sharifipour, J. S. Huang, P. Liao, L. Huber, and M. M. Jovanovic, "Manufacturing and cost analysis of power-factor-correction circuits," Applied Power Electronics Conference and Exposition, 1998. APEC'98. Conference Proceedings 1998. Thirteenth Annual, vol. 1, 1998.
10 J. P. Noon, "Designing high-power factor off-line power supplies," Texas Instruments Incorporated, pp. 2-1-2-35, 2003.
11 Williams, James B. "Design of feedback loop in unity power factor AC to DC converter," Power Electronics Specialists Conference, 1989. PESC'89 Record., 20th Annual IEEE. IEEE, 1989.
12 L. H. Dixon, Jr, "High power factor preregulators for off-line power supplies," Unitrode Corporation, pp. 6-1-6-16, 2003.
13 C. S. Lin, T. M. Chen, and C. L. Chen, "Analysis of low frequency harmonics for continuous conduction mode boost power factor correction," IEE Proc.-Electr, Power Appl, vol. 148, no. 2, Mar. 2001.
14 Y. H. Lho, "A study on effective control methodology for DC/DC converter," Journal of Institute of Control, Robotics and System (in Korean), vol. 20, no. 7, pp. 756-759, May 2014.   DOI
15 S. G. Choi, "Interval-based controller design considering parameter variations for DC/DC converters," Journal of Institute of Control, Robotics and System (in Korean), vol. 19, no. 10, pp. 879-885, Sep. 2013.   DOI