A Brief Overview of On-Chip Voltage Regulation in High-Performance and High-Density Integrated Circuits

With the increase of density and complexity of high performance integrated circuits and systems, including many-core chips and system-on-chip (SoC), it is becoming difficult to meet the power delivery and regulation requirements with off-chip regulators. The off-chip regulators become a less attract...

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Veröffentlicht in:	IEEE access 2021, Vol.9, p.813-826
Hauptverfasser:	Ahmed, Farid Uddin, Sandhie, Zarin Tasnim, Ali, Liaquat, Chowdhury, Masud H.
Format:	Artikel
Sprache:	eng
Schlagworte:	capless low-dropout regulator Complexity Density Design optimization Design specifications Electric power Electricity generation Industrial research Integrated circuits Integrity interleaving Linear regulator low-dropout regulator Microprocessors on-chip power delivery system on-chip voltage regulation Optimization techniques Regulators switched-capacitor regulator Switches Switching circuits switching regulator System on chip Transistors Voltage control Voltage regulators
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description	With the increase of density and complexity of high performance integrated circuits and systems, including many-core chips and system-on-chip (SoC), it is becoming difficult to meet the power delivery and regulation requirements with off-chip regulators. The off-chip regulators become a less attractive choice because of the higher overheads and complexity imposed by the additional wires, pins, and pads. The increased I^{2}R loss makes it challenging to maintain the integrity of different voltage domains under a lower supply voltage environment in the smaller technology nodes. Fully integrated on-chip voltage regulators have proven to be an effective solution to mitigate power delivery and integrity issues. Recently, there has been a surge of interest among the academic and industrial research communities to explore and design different types of on-chip voltage regulators. This survey presents a brief overview of the on-chip power delivery system and the classification and working principles of on-chip voltage regulators. The main focus of this review paper is to provide a comprehensive study of two of the most promising on-chip voltage regulators - (i) the low-drop-out (LDO) regulator and (ii) the switched-capacitor (SC) regulator. This article elaborates on the design specifications, optimization techniques, advantages, and limitations of LDO and SC type on-chip voltage regulators.
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The main focus of this review paper is to provide a comprehensive study of two of the most promising on-chip voltage regulators - (i) the low-drop-out (LDO) regulator and (ii) the switched-capacitor (SC) regulator. 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subjects	capless low-dropout regulator Complexity Density Design optimization Design specifications Electric power Electricity generation Industrial research Integrated circuits Integrity interleaving Linear regulator low-dropout regulator Microprocessors on-chip power delivery system on-chip voltage regulation Optimization techniques Regulators switched-capacitor regulator Switches Switching circuits switching regulator System on chip Transistors Voltage control Voltage regulators
title	A Brief Overview of On-Chip Voltage Regulation in High-Performance and High-Density Integrated Circuits
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