Green semiconductor technology with ultra-low power on-chip charge-recycling power circuit and system

Kazuhiro Ueda; Okura Shunsuke; Fukashi Morishita; Kazutami Arimoto; Leona Okamura; Tsutomu Yoshihara

doi:10.1109/IPEC.2012.6522638

Green semiconductor technology with ultra-low power on-chip charge-recycling power circuit and system

Kazuhiro Ueda, Okura Shunsuke, Fukashi Morishita, Kazutami Arimoto, Leona Okamura, Tsutomu Yoshihara

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution

1 Citation (Scopus)

Abstract

For low power consumption which makes more than doubles a battery life, the charge-recycling system by reuse the energy between the two or more CPUs and the task scheduling technique for high efficiency are proposed. In this architecture, CPUs are divided into upper and lower load groups, and electrical charges are shared among the stacked CPUs and a tank capacitor. To control divided loads, a high speed and efficient regulator are needed. The internal circuit voltage variation between upper and lower modules is solved by seven LDO regulators, boosting switched capacitor and the tank capacitor. As a result, the stable voltage can be supplied to each CPU, even if upper and lower loads are different or battery is used. The LDOs improve the margin of accumulation of tank capacitor or task schedule operation, and the power efficiency is raised further. The system can be on-chip without external large control circuit and inductor like switching regulator. The test chips were fabricated using 90nm standard CMOS technology. Although the power efficiency of the conventional system with a simple LDO is 44.4% at the maximum, that of the proposed charge-recycling system improves to 88.9%.

Original language	English
Title of host publication	Proceedings - 2012 IEEE Asian Solid-State Circuits Conference, A-SSCC
Pages	105-108
Number of pages	4
DOIs	https://doi.org/10.1109/IPEC.2012.6522638
Publication status	Published - 2012
Event	2012 IEEE Asian Solid-State Circuits Conference, A-SSCC 2012 - Kobe Duration: 2012 Nov 12 → 2012 Nov 14

Other

Other	2012 IEEE Asian Solid-State Circuits Conference, A-SSCC 2012
City	Kobe
Period	12/11/12 → 12/11/14

ASJC Scopus subject areas

Hardware and Architecture
Electrical and Electronic Engineering

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10.1109/IPEC.2012.6522638

Cite this

Ueda, K, Shunsuke, O, Morishita, F, Arimoto, K, Okamura, L & Yoshihara, T 2012, Green semiconductor technology with ultra-low power on-chip charge-recycling power circuit and system. in Proceedings - 2012 IEEE Asian Solid-State Circuits Conference, A-SSCC., 6522638, pp. 105-108, 2012 IEEE Asian Solid-State Circuits Conference, A-SSCC 2012, Kobe, 12/11/12. https://doi.org/10.1109/IPEC.2012.6522638

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abstract = "For low power consumption which makes more than doubles a battery life, the charge-recycling system by reuse the energy between the two or more CPUs and the task scheduling technique for high efficiency are proposed. In this architecture, CPUs are divided into upper and lower load groups, and electrical charges are shared among the stacked CPUs and a tank capacitor. To control divided loads, a high speed and efficient regulator are needed. The internal circuit voltage variation between upper and lower modules is solved by seven LDO regulators, boosting switched capacitor and the tank capacitor. As a result, the stable voltage can be supplied to each CPU, even if upper and lower loads are different or battery is used. The LDOs improve the margin of accumulation of tank capacitor or task schedule operation, and the power efficiency is raised further. The system can be on-chip without external large control circuit and inductor like switching regulator. The test chips were fabricated using 90nm standard CMOS technology. Although the power efficiency of the conventional system with a simple LDO is 44.4% at the maximum, that of the proposed charge-recycling system improves to 88.9%.",

author = "Kazuhiro Ueda and Okura Shunsuke and Fukashi Morishita and Kazutami Arimoto and Leona Okamura and Tsutomu Yoshihara",

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doi = "10.1109/IPEC.2012.6522638",

language = "English",

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AU - Ueda, Kazuhiro

AU - Shunsuke, Okura

AU - Morishita, Fukashi

AU - Arimoto, Kazutami

AU - Okamura, Leona

AU - Yoshihara, Tsutomu

PY - 2012

Y1 - 2012

N2 - For low power consumption which makes more than doubles a battery life, the charge-recycling system by reuse the energy between the two or more CPUs and the task scheduling technique for high efficiency are proposed. In this architecture, CPUs are divided into upper and lower load groups, and electrical charges are shared among the stacked CPUs and a tank capacitor. To control divided loads, a high speed and efficient regulator are needed. The internal circuit voltage variation between upper and lower modules is solved by seven LDO regulators, boosting switched capacitor and the tank capacitor. As a result, the stable voltage can be supplied to each CPU, even if upper and lower loads are different or battery is used. The LDOs improve the margin of accumulation of tank capacitor or task schedule operation, and the power efficiency is raised further. The system can be on-chip without external large control circuit and inductor like switching regulator. The test chips were fabricated using 90nm standard CMOS technology. Although the power efficiency of the conventional system with a simple LDO is 44.4% at the maximum, that of the proposed charge-recycling system improves to 88.9%.

AB - For low power consumption which makes more than doubles a battery life, the charge-recycling system by reuse the energy between the two or more CPUs and the task scheduling technique for high efficiency are proposed. In this architecture, CPUs are divided into upper and lower load groups, and electrical charges are shared among the stacked CPUs and a tank capacitor. To control divided loads, a high speed and efficient regulator are needed. The internal circuit voltage variation between upper and lower modules is solved by seven LDO regulators, boosting switched capacitor and the tank capacitor. As a result, the stable voltage can be supplied to each CPU, even if upper and lower loads are different or battery is used. The LDOs improve the margin of accumulation of tank capacitor or task schedule operation, and the power efficiency is raised further. The system can be on-chip without external large control circuit and inductor like switching regulator. The test chips were fabricated using 90nm standard CMOS technology. Although the power efficiency of the conventional system with a simple LDO is 44.4% at the maximum, that of the proposed charge-recycling system improves to 88.9%.

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Green semiconductor technology with ultra-low power on-chip charge-recycling power circuit and system

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