A DC-DC buck converter chip with integrated PWM/PFM hybrid-mode control circuit

This paper proposes a DC-DC buck power converter chip with a novel integrated PWM/PFM hybrid-mode control. The DC-DC converter chip with synchronous rectifier not only uses current-mode feedback control but also possesses constant-frequency-mode control and hybrid-mode control functions at the same time. Furthermore, the operational modes of the converter can be selected by an external voltage signal. In the part of constant-frequency-mode control, as the inductor current is below zero, the synchronous rectifier switch of the converter will be automatically turned off in order to reduce the loss of the reverse inductor current. About the hybrid-mode control, the operational modes of the converter can be judged by the proposed PWM/PFM hybrid-mode control circuit. When the converter is operated in CCM, the constant-frequency-mode control is applied and when the inductor current is in DCM, the converter is operated under the variable-frequency-mode control. At this moment, the switching frequency of the converter is designed to decrease proportionally with the load to reduce the high switching loss at light load. The synchronous rectifier switch will also be turned off in order to reduce the reverse conduction loss. All the above functions are integrated in one chip. Simulation and experimental results verify that the converter chip works functionally. The power converter chip with PWM/PFM hybrid-mode control proposed here is very suitable for the portable electronic products with the requirements of low voltage, low power, high efficiency, and wide load range.

[1]  Biranchinath Sahu,et al.  A high-efficiency, dual-mode, dynamic, buck-boost power supply IC for portable applications , 2005, 18th International Conference on VLSI Design held jointly with 4th International Conference on Embedded Systems Design.

[2]  Philip K. T. Mok,et al.  On-chip current sensing technique for CMOS monolithic switch-mode power converters , 2002, 2002 IEEE International Symposium on Circuits and Systems. Proceedings (Cat. No.02CH37353).

[3]  R.B. Ridley,et al.  A new continuous-time model for current-mode control with constant frequency, constant on-time, and constant off-time, in CCM and DCM , 1990, 21st Annual IEEE Conference on Power Electronics Specialists.

[4]  Robert W. Erickson,et al.  DC-DC converter design for battery-operated systems , 1995, Proceedings of PESC '95 - Power Electronics Specialist Conference.

[5]  Fred C. Lee,et al.  Improved light-load efficiency for synchronous rectifier voltage regulator module , 2000 .

[6]  Fred C. Lee,et al.  Optimizing design for low voltage DC-DC converters , 1997, Proceedings of APEC 97 - Applied Power Electronics Conference.

[7]  Gyu-Hyeong Cho,et al.  An integrated CMOS DC-DC converter for battery-operated systems , 1999, 30th Annual IEEE Power Electronics Specialists Conference. Record. (Cat. No.99CH36321).

[8]  Ka Nang Leung,et al.  An integrated CMOS current-sensing circuit for low-Voltage current-mode buck regulator , 2005, IEEE Transactions on Circuits and Systems II: Express Briefs.

[9]  F. C. Lee,et al.  A low voltage high efficiency and high power density DC/DC converter , 1997, PESC97. Record 28th Annual IEEE Power Electronics Specialists Conference. Formerly Power Conditioning Specialists Conference 1970-71. Power Processing and Electronic Specialists Conference 1972.

[10]  Narisi Wang,et al.  A digitally controlled DC/DC converter for an RF power amplifier , 2006, IEEE Transactions on Power Electronics.

[11]  P.K.T. Mok,et al.  A monolithic current-mode CMOS DC-DC converter with on-chip current-sensing technique , 2004, IEEE Journal of Solid-State Circuits.