一种低功耗的片上线性调节器,由开关电容辅助,用于快速瞬态调节

Suming Lai, Peng Li
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引用次数: 1

摘要

本文介绍了一种采用商用90纳米CMOS技术设计的无输出电容低差稳压器,用于低压应用。通过显著降低其降压和静态电流消耗,提高了稳压器的功率效率。采用开关电容技术的新型辅助电路补偿了其暂态调节性能的下降。该稳压器在1V电源电压下工作,输出0.9V,最大直流电流为100mA。满负荷状态下功率效率约为90%,轻载状态下(负载电流1mA)功率效率保持在86%以上。暂态性能方面,施加100mA负载电流步进,升/降时间为5ns时,输出电压降和超调量均在稳态值的10%以内,而不加辅助电路则超过40%。蒙特卡罗和温度扫描仿真结果表明,LDO对工艺和温度变化以及器件不匹配具有较强的鲁棒性。
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A power-efficient on-chip linear regulator assisted by switched capacitors for fast transient regulation
This paper presents an output-capacitorless low-dropout voltage regulator designed in a commercial 90nm CMOS technology for low-voltage applications. The power efficiency of the regulator is enhanced by significantly reducing its dropout voltage and quiescent current consumption. The resultant degradation of its transient regulation performance is compensated by a novel auxiliary circuit using switched-capacitor technique. The regulator operates under 1V supply voltage with a 0.9V output and delivers a maximum DC current of 100mA. The power efficiency under the full-load condition is about 90% and under the light-load condition (1mA load current) it maintains above 86%. For transient performance, when a 100mA load current step with 5ns rise/fall time is applied, the output voltage droop and overshoot are both within 10% of the steady-state value, while it would exceed 40% without the auxiliary circuit. Monte Carlo and temperature-sweep simulation results show that the LDO is robust to process and temperature variations and device mismatches.
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