[1] MA D, BONDADE R. Enabling power-efficient DVFS operations on silicon [J]. IEEE Circuits and Systems Magazine, 2010, 10(1): 14-30.
[2] MOHAN N, ROBBINS W P, IMBERTSON P, et al. Restructuring of first courses in power electronics and electric drives that integrates digital control [J]. Power Electronics, 2003, 18(1): 429-437.
[3] LOU J, WU X. Design of multi-mode 4-switch buck-boost controller [C]∥ Proceedings of the 14th ACM/IEEE International Symposium Low Power Electronics and Design. San Francisco: ACM, 2009: 311-314.
[4] LENK R. Application bulletin AB-20 optimum current-sensing techniques in CPU converters [R]. USA: Fairchild Semiconductor, 1999.
[5] PAUL R, DRAGAN M. Analysis of PWM nonlinearity in non-inverting buck-boost power converters [C]∥ Power Electronics Specialists Conference. Rhodes: IEEE, 2008: 3741-3747.
[6] PAUL R, DRAGAN M. Smooth transition and ripple reduction in 4-switch non-inverting buck-boost power converter for WCDMA RF power amplifier [C]∥ International Symposium on Circuits and Systems. Seattle: IEEE, 2008: 3266-3269.
[7] SANCHEZ-SINENCIO E, ANDREOU A. Low-voltage/low-power integrated circuits and systems [M]. New York: IEEE, 1998.
[8] LUO F, MA D. Design of digital tri-mode adaptive-output buck-boost power converter for power-efficient integrated systems [J]. IEEE Transactions on Industrial Electronics, 2010, 57(6): 2151-2160.
[9] SAHU B, RINCON-MORA G A. A high-efficiency, dual-mode, dynamic, buck-boost power supply IC for portable applications [C]∥ Proceedings of the 18th International Conference on VLSI Design. Kolkata: IEEE, 2005: 858-861.
[10] SAHU B, RINCON-MORA G A. A low voltage, dynamic, noninverting, synchronous buck-boost converter for portable applications [J]. IEEE Transactions Power Electronics, 2004, 19(2): 443-452.
[11] MURO K, NABESHIMA T, SATO T, et al. H-bridge buck-boost converter with dual feedforward control [C]∥ Proceedings of the International Conference on 8th Power Electronics and Drive Systems. Taiwan: IEEE, 2009: 1002-1007. |