一种无帽LDO低功率电压尖峰检测电路

Q3 Engineering

International Journal of Electronics Letters Pub Date : 2021-09-02 DOI:10.1080/21681724.2021.1966657

P. Manikandan, B. Bindu

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引用次数: 0

摘要

提出了一种用于无帽低差稳压器(LDO)的低功率电压尖峰检测(VSD)电路。LDO基于级联编码翻转电压从动器(CAFVF)拓扑结构，输出电压的瞬态由尖峰检测电路控制，这些电路仅在瞬态期间被激活。超调电压尖峰检测(OVSD)电路通过中间电压检测输出电压，并通过对栅极电容充电来降低功率MOSFET的电流，并在输出电压上升时恢复输出电压。欠冲电压尖峰检测(UVSD)电路直接检测输出电压，并通过释放栅极电容增加通过功率MOSFET的电流，并在输出电压下降时恢复输出电压。在稳定状态下，VSD电路只消耗一个偏置电流。该LDO采用CMOS技术实现，具有良好的负载瞬态响应，稳定时间为负载电流范围内的最大电压尖峰。

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A Low Power Voltage Spike Detection Circuit for Cap-less LDO

ABSTRACT A low-power voltage spike detection (VSD) circuit for a cap-less low-dropout regulator (LDO) is presented in this paper. The LDO is based on the cascoded flipped voltage follower (CAFVF) topology, and the transients in the output voltage are controlled by the spike detection circuits and these circuits get activated only during the transient period. The overshoot voltage spike detection (OVSD) circuit senses the output voltage via intermediate voltage and reduces the current through the power MOSFET by charging the gate capacitance and restores the output voltage whenever the output voltage rises. The undershoot voltage spike detection (UVSD) circuit directly detects the output voltage and increases the current through the power MOSFET by discharging the gate capacitance and restores back the output voltage whenever the output voltage drops. The VSD circuit consumes only a bias current of in the steady state. This LDO is implemented in CMOS technology and achieved a good load transient response with settling time with the maximum voltage spike of over the load current range of to .

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来源期刊

International Journal of Electronics Letters Engineering-Electrical and Electronic Engineering

CiteScore

1.80

自引率

0.00%

发文量

期刊介绍： International Journal of Electronics Letters (IJEL) is a world-leading journal dedicated to the rapid dissemination of new concepts and developments across the broad and interdisciplinary field of electronics. The Journal welcomes submissions on all topics in electronics, with specific emphasis on the following areas: • power electronics • embedded systems • semiconductor devices • analogue circuits • digital electronics • microwave and millimetre-wave techniques • wireless and optical communications • sensors • instrumentation • medical electronics Papers should focus on technical applications and developing research at the cutting edge of the discipline. Proposals for special issues are encouraged, and should be discussed with the Editor-in-Chief.