A dual-mode fast-transient average-current-mode buck converter without slope-compensation

Abstract

A dual-mode fast-transient average-current-mode buck converter without slope-compensation is proposed in this paper. The benefits of the average-current-mode are fast-transient response, simple-compensation design, and no requirement for slope-compensation, furthermore, that minimizes some power management problems, such as EMI, size, design complexity, and cost. Average-current-mode control employs two loop control methods, an inner loop for current and an outer one for voltage. The proposed buck converter using the current sensing and average-current-mode control techniques can be stable even if the duty cycle is greater than 50%. It which can adaptively switch between pulse-width modulation (PWM) and pulse-frequency modulation (PFM) is operated with very high conversion efficiency. Under light load condition, the proposed buck converter enters PFM mode to decrease the output ripple. That can be switch to PWM mode to realize a smooth transition under heavy load condition. Therefore, PFM is used to improve the efficiency at light load. Dual-mode buck converter has very high conversion efficiency over a wide load conditions. The proposed buck converter has been fabricated with TSMC 0.35μm CMOS 2P4M processes, the total chip area is 1.45 × 1.11mm2. Maximum output current is 450mA at the output voltage 1.8V. When the supply voltage is 3.6V, the output voltage can be 0.8V∼2.8V. Maximum transient response is less than 10μs. Finally, the theoretical analysis is verified to be correct by simulations and experiments.