Three-Stage CMOS LDO with Optimized Power and Dynamic Performance for Portable Devices

Low dropout (LDO) regulators are crucial components in power management systems for portable, i.e., battery-powered, devices. However, the design of LDO regulators presents a challenging trade-off between dynamic performance, power consumption, and area efficiency. This paper proposes a novel LDO regulator design that addresses these challenges by employing the reverse nested Miller compensation (RNMC) with current buffers embedded within the own class AB high gain error amplifier (EA) topology, and a time response enhancement circuit (TREC). High-gain (>120 dB) class AB EA renders good regulation performance with enhanced dynamic performance. The proposed compensation scheme improves the gain bandwidth product (GBW) and stability of the regulator, while the TREC reduces overshoot and undershoot during load transients without additional steady-state power consumption. Post-layout simulations confirm the robustness of the proposed 180 nm CMOS design across a wide range of operating conditions, achieving a regulated output voltage of 1.8 V with 100 mV dropout, good load and line regulating performance, and excellent load transient response with reduced undershoot and overshoot at minimum power (I-q = 13.8 mu A) and area (314 mu m x 150 mu m) consumption. The proposed LDO regulator thus offers a compelling compromise between power consumption, area efficiency, and dynamic performance, making it highly suitable for portable applications.

Automated summary

This paper proposes a novel LDO regulator design that addresses the trade-off between dynamic performance, power consumption, and area efficiency. The proposed design improves the gain bandwidth product and stability of the regulator and reduces overshoot and undershoot during load transients without additional steady-state power consumption. The post-layout simulations confirm the robustness of the proposed design, achieving good load and line regulating performance with reduced undershoot and overshoot at minimum power and area consumption.