低功率大型乘法器高階數位電路之功率最佳化

Chian-Lin LIU; 劉倩綝

Please use this identifier to cite or link to this item: http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/37800

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???org.dspace.app.webui.jsptag.ItemTag.dcfield???	Value	Language
dc.contributor.advisor	郭正邦
dc.contributor.author	Chian-Lin LIU	en
dc.contributor.author	劉倩綝	zh_TW
dc.date.accessioned	2021-06-13T15:44:29Z	-
dc.date.available	2013-07-07
dc.date.copyright	2008-07-07
dc.date.issued	2008
dc.date.submitted	2008-07-02
dc.identifier.citation	[1] J.B. Kuo, J. Lou, 'Low-Voltage CMOS VLSI Circuits,' Wiley, New York,1999. [2] ITRS, 'http://www.itrs.netlCommon/2004Update/ 2004Update.htm.' [3] G .E. Moore, 'Progress in Digital lntegrated Electronics,' International Electron Devices Meeting, Vol. 21, pp. 11-13, 1975. [4] P.P. Gelsinger, 'Microprocessors for the new millennium: Challenges, opportunities, and new frontiers,' lnternational Solid-state Circuits Conference, pp. 22-25, Feb. 2001. [5] 'Power Compiler User Guide,'2007,03. [6] H.J.M. Veendrick, 'Short-circuit dissipation of static CMOS circuitry and its impact on the design of buffer circuits,' IEEE Journal of Solid-state Circuits, Vol. 19, lssue 4, pp. 468-473, Aug 1984. [7] S. Mukhopadhyay, K. Roy, 'Leakage Estimation and Leakage Control for Nano-Scale CMOS Circuits,' Design Automation Conference, 2004. [8] J.B. Kuo, 'CMOS Digital IC,' McGraw-Hill, Taiwan, 1996. [9] R.X. Gu, M.I. Elmasry, 'Power dissipation analysis and optimization of deep submicron CMOS digital circuits,' IEEE Journal of Solid-state Circuits, Vol. 31, lssue 5, pp. 707-71 3, May 1996. [10] Power Modelling and Leakage Reduction, 'http://eda.ee.ucla.edu/ EE201A-04Spring/leakage~pres.ppt' [11] B. Chung and J.B.Kuo, 'Gate-level dual-threshold static power optimization methodology (GDSPOM) using path-based static timing analysis (STA) technique for SOC application' [12] L. Wei, Z. Chen, M. Johnson, K. Roy, V. De, 'Design and optimization of low voltage high performance dual threshold CMOS circuits,' Design Automation Conference, pp. 489-494, Jun 1998. [13] L. Wei, 2. Chen, K. Roy, M.C. Johnson, Y. Ye, V.K. De, 'Design and optimization of dual-threshold circuits for low-voltage low-power applications,' IEEE Transactions on Very Large Scale Integration (VLSI) Systems, Vol. 7, lssue 1, pp. 16-24, March 1999. [14] N.P. Jouppi, 'Timing Analysis and Performance Improvement of MOS VLSI Designs,' IEEE Transactions on Computer-Aided Design of Low-voltage Energy-Constrained CMOS Circuits,' International Conference on VLSI Design, pp. 193-198, Jan 2002. [15] D. Samanta, A. Pal, 'Optimal Dual-VT Assignment for Low-voltage Energy-Constrained CMOS Circuits,' International Conference on Design, pp. 193-198, Jan 2002. [16] D. Samanta, A. Pal, 'Optimal Dual-VT Assignment for Low-voltage Energy-Constrained CMOS Circuits,' International Conference on VLSI Design, pp. 193-198, Jan 2002. [17] Q. Wang, S. Vrudhula, 'Algorithms for Minimizing Standby Power in Deep Submicrometer, Dual-Vt CMOS Circuits,' IEEE Trans. Computer- Aided Design of IC and Systems, Vol. 21, No. 3, pp. 306-31 8, March 2002. [18] C. S. Wallace, 'A suggestion for a fast multiplier', IEEE Trans. Computers,Vol. EC-13, pp. 14-17, February 1964. [19] 'Hardware algorithms for parallel multiplication,' http://www.aoki.ecei.tohoku.ac.jp/arith/mg/algorithm.html.Accessed on May 15,2005. [20] Jeng-Shiun Jan, 'A Low-Power and High-Performance Function Generator for Multiplier-Based Arithmetic Operations,”2001. [21] CIC UMC/FARADAY FSD0C_A 90nm Standard Core Cell, FSD0T_A 90nm Standard Core Cell. [22] Synopsys, 'PrimeTime User Guide,'2007.06. [23] Y. Zhang, H. H. Chen, and J.B. Kuo, '0.8V CMOS Adiabatic Differential Switch Logic Circuit Using Bootstrap Techniques for Low-Voltage Low- Power VLSI,' Electron. Lett., Vol. 38, No. 24, pp. 1497-1499, 2002. [24] H.P. Chen and J. 6. Kuo, 'A 0.8V CMOS TSPC Adiabatic DCVS Logic Circuit with the Bootstrap Technique for Low-Power VLSI,' ICECS Proceedings, pp. 175-1 78,2004. [25] Q. Wu; M. Pedram, X. Wu, 'Clock-gating and its application to low power design of sequential circuits', IEEE Transactions on Circuits and Systems,Vol. 47, Issue 3, pp. 415-420, March 2000.
dc.identifier.uri	http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/37800	-
dc.description.abstract	由於矽積體電路製程的特徵及尺寸縮小到深次微米元件，現今積體電路設計的技術，可將更多電路集合在單一晶片上，而這麼多元件在同一個晶片上面，不僅電路設計上變複雜，要維持電路有良好的效能，最重要必須考慮到的就是功率消耗的問題。這篇論文裡，我們主要是探討新的邏輯閘層級兩個臨界電壓最佳化靜態功率方法(novel gate-level dual-threshold static power optimization methodology；GDTPOM)這個演算法，這個演算法是利用Synopsys PrimeTime工具以及靜態時序分析(static timing analysis)的方法，針對用90nm MTCMOS的製程設計一個速度快、功率消耗小的晶片系統。在我們分析的過程中，主要是使用到裡面高臨界電壓以及低臨界電壓的標準元件資料庫(cell library)，因為高臨界電壓的標準元件資料庫優點是具有較低的消耗功率，而低臨界電壓的標準元件資料庫優點是具有較快的操作速度。我們先設計一個16 bits乘法器的數位電路，利用兩個不同臨界電壓的標準元件資料庫來分析，使用新思(synopsys)公司所開發的PrimeTime工具加入靜態時序分析方法來達到我們所希望電路速度的要求，並且利用此最佳化16bits乘法器的結果結合成超大型32bits乘法器電路。實驗結果發現不僅16 bits或32 bits乘法器與全部都由低臨界電壓cell組成的電路比較，都可以在電路速度要求下達到將近50%的leakage power消耗。	zh_TW
dc.description.abstract	As integrated-circuit (IC) technology advances to into deep-submicron (DSM) regime, more functionality can be combined into a single chip. To design such a complex device, low power consumption has become a significant requirement. If you want to design a high performance circuit, you should keep power consumption. The paper describe a novel gate-level dual-threshold static power optimization methodology (GDSPOM), which is based on the static timing analysis technique using Synopsys PrimeTime tool for designing high-speed low-power SOC applications dealing with 90nm MTCMOS technology. The cell libraries come in fixed threshold - high Vt for low static power and low Vt for high speed. Based on this optimization technique using two cell libraries with different threshold voltages, a 16-bit multiplier using the dual-threshold cells meeting the speed requirement has been designed to have a 50% less leakage power consumption when compared to the one using only the low-threshold cell library. And then we get the optimized 16 bits multiplier to combined a large size 32 bits multiplier. We can get the good result ─ 50% less leakage power consumption using 16 bits or 32bits multiplier.	en
dc.description.provenance	Made available in DSpace on 2021-06-13T15:44:29Z (GMT). No. of bitstreams: 1 ntu-97-R95943137-1.pdf: 6263992 bytes, checksum: cad71e2818984403e87a85d149c203e4 (MD5) Previous issue date: 2008	en
dc.description.tableofcontents	口試委員會審定書…………………………………………………………………i 致謝 iii 中文摘要 iv ABSTRACT v 圖表 viii 演算法 x 表格 xi Chapter 1 簡介 1 1.1 互補式矽金氧半(CMOS)超大型積體電路的源由 1 1.2 功率消耗的構成因素 2 1.3 研究目標 5 1.4 論文的架構 7 Chapter 2 有關MTCMOS最佳化演算法的研究 8 2.1 MTCMOS的原理 8 2.2 由低Vt至高Vt的演算法 9 2.2.1 廣度優先搜尋 10 2.2.2 分層搜尋 12 2.3 由高Vt至低Vt的演算法 15 2.4 Fine-Grained Vt Assignment演算法 17 2.4.1 最小分割 (Min-Cut) 17 2.4.2 最大分割I (Max-Cut I) 19 2.4.3 最大分割II (Max-Cut II) 23 2.5 限制因素 24 2.6 32bits乘法器 24 Chapter 3 利用兩種邏輯層級的臨界電壓做總功率最佳化的方法 (Gate-Level Dual-Threshold Static Power Optimization Methodology； 30 3.1 標準元件資料庫和模型 31 3.1.1 標準元件資料庫 31 3.1.2 時間模型 32 3.1.3 功率模型 37 3.2 GDSPOM流程圖 39 3.3 效能 44 Chapter 4 結論及未來研究方向 53 參考文獻 55
dc.language.iso	zh-TW
dc.subject	邏輯閘層級兩個臨界電壓最佳化靜態功率最佳化的方法	zh_TW
dc.subject	多元臨界電壓之互補式矽金氧半	zh_TW
dc.subject	靜態時序分析	zh_TW
dc.subject	MTCMOS	en
dc.subject	STA	en
dc.subject	GDSPOM	en
dc.title	低功率大型乘法器高階數位電路之功率最佳化	zh_TW
dc.title	High-Level Power Optimization of Low-Power Large-Size Multiplier Circuits	en
dc.type	Thesis
dc.date.schoolyear	96-2
dc.description.degree	碩士
dc.contributor.oralexamcommittee	林浩雄,林吉聰,陳正雄,蔡成宗
dc.subject.keyword	邏輯閘層級兩個臨界電壓最佳化靜態功率最佳化的方法,多元臨界電壓之互補式矽金氧半,靜態時序分析,	zh_TW
dc.subject.keyword	GDSPOM,MTCMOS,STA,	en
dc.relation.page	57
dc.rights.note	有償授權
dc.date.accepted	2008-07-03
dc.contributor.author-college	電機資訊學院	zh_TW
dc.contributor.author-dept	電子工程學研究所	zh_TW
Appears in Collections:	電子工程學研究所

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