Performance analysis of a complete adiabatic logic system driven by the proposed power clock generator

Performance analysis of a complete adiabatic logic system driven by the proposed power clock generator

导出

摘要 We analyze the energy performance of a complete adiabatic circuit/system including the Power Clock Generator （PCG） at the 90 nm CMOS technology node. The energy performance in terms of the conversion efficiency of the PCG is extensively carried out under the variations of supply voltage, process comer and the driver transistor＇s width. We propose an energy-efficient singe cycle control circuit based on the two-stage comparator for the synchronous charge recovery sinusoidal power clock generator （PCG）. The proposed PCG is used to drive the 4-bit adiabatic Ripple Carry Adder （RCA） and their simulation results are compared with the adiabatic RCA driven by the reported PCG. We have also simulated the logically equivalent static CMOS RCA circuit to compare the energy saving of adiabatic and non-adiabatic logic circuits. In the clock frequency range from 25 MHz to 1GHz, the proposed PCG gives a maximum conversion efficiency of 56.48%. This research work shows how the design of an efficient PCG increases the energy saving of adiabatic logic. We analyze the energy performance of a complete adiabatic circuit/system including the Power Clock Generator （PCG） at the 90 nm CMOS technology node. The energy performance in terms of the conversion efficiency of the PCG is extensively carried out under the variations of supply voltage, process comer and the driver transistor＇s width. We propose an energy-efficient singe cycle control circuit based on the two-stage comparator for the synchronous charge recovery sinusoidal power clock generator （PCG）. The proposed PCG is used to drive the 4-bit adiabatic Ripple Carry Adder （RCA） and their simulation results are compared with the adiabatic RCA driven by the reported PCG. We have also simulated the logically equivalent static CMOS RCA circuit to compare the energy saving of adiabatic and non-adiabatic logic circuits. In the clock frequency range from 25 MHz to 1GHz, the proposed PCG gives a maximum conversion efficiency of 56.48%. This research work shows how the design of an efficient PCG increases the energy saving of adiabatic logic.

作者 Jitendra Kanungo S.Dasgupta

机构地区 Department of Electronics & Communication Engineering Microelectronics & VLSI Group

出处《Journal of Semiconductors》 EI CAS CSCD 2014年第9期97-103,共7页 半导体学报（英文版）

基金 Project supported by the Special Man-Power Development Programme in VLSI & Related Software,Phase-Ⅱ(SMDP-Ⅱ),Ministry of Information Technology,Government of India the JUET,Guna(M.P.)

关键词 clock-generator energy recovery logic low power single phase sinusoidal clock clock-generator energy recovery logic low power single phase sinusoidal clock

分类号 TN432 [电子电信—微电子学与固体电子学]

引文网络
相关文献

参考文献30

1Dikinson A G, Denkar J S. Adiabatic dynamic logic. IEEE J Solid-State Circuits, 1995, 30(3): 311.
2Mahmoodi-Meimand H, Afzali-Kusha A. Efficient power clock generation for adiabatic logic. Proc IEEE Int Symposium on Cir- cuits and Systems (ISCAS), 2001, 4:642.
3Athas W C, Svensson L J, Tzartzanis N. A resonant signal driver for two-phase, almost-non-overlapping clocks. Proceedings of the International Symposium on Circuits and Systems, 1996:12.
4Maksimovic D, Oklobdzija V G. Integrated power clock genera- tors for low energy logic. Proceedings oflEEE Power Electronics Specialists Conference, 1995:61.
5Nayan A N, Takahashi Y, Sekine T. LSI implementation of a low- power 4 × 4-bit array two-phase clocked adiabatic static CMOS logic multiplier. Microelectron J, 2012, 43(4): 244.
6Moon Y, Jeong D K. A 32 × 32-b adiabatic register file with supply clock generator. IEEE J Solid-State Circuits, 1998, 33(5): 696.
7Arsalan M, Shams M. Charge-recovery power clock generators for adiabatic logic circuits. Proc 18th International Conference on VLSI Design, 2005:171.
8Maksimovic D, Oklobdzija V G, Nikolic B, et al. Clocked CMOS adiabatic logic with integrated single-phase power-clock supply. IEEE Trans Very Large Scale Integration (VLSI) Systems, 2000, 8(4): 460.
9Marjonen J, Aberg M. A single phase clocked adiabatic static logic-a proposal for digital low power applications. Kluwer Academic Pub J of VLSI Signal Processing, 2001, 27:253.
10Maksimovic D, Oklobdzija V G. Integrated power clock genera- tors for low energy logic. Proc 26th IEEE Annual Conf on Power Electronics Specialists (PESC), 1995, 1:61.

1AMD发布一系列节能CPU节能性能提高近一倍[J].华南金融电脑,2006,14(6):45-45.
2姜哲.浅谈变频器应用中干扰的抑制[J].科技信息,2010(27):97-97. 被引量：2
3Xu Zhuang Yu HuiYue Zhang Hui LinXia.Design of A 1.2 V Low-Power Clock Generator[J].半导体技术,2011,36(12):953-956.
4季悦,吴德刚.变频器应用中的干扰及其抑制[J].科技信息,2010(16).
5马甲.节能性能两不误轻松晋级“开核”达人[J].电脑爱好者,2011(2):68-68.
6我国中压变频器高速增长念势将保持[J].变频技术应用,2014,9(1):41-42.
7杨周行.微波通信的故障定位逻辑系统[J].无线通信技术,2001,10(1):45-49.
8飞利浦新款19寸霓彩LED液晶196E3L上市[J].计算机与网络,2011,37(7):14-14.
9飞利浦P系列高端显示器273P3L震撼上市[J].计算机与网络,2011,37(12):16-16.
10晓慧.节能性能都要——双卡切换商务本导购[J].电脑知识与技术（经验技巧）,2010(5):68-71.

Journal of Semiconductors

2014年第9期

浏览历史

内容加载中请稍等...

Performance analysis of a complete adiabatic logic system driven by the proposed power clock generator

参考文献30

相关作者

相关机构

相关主题

浏览历史