A 160 MHz 32 b 0.5 W CMOS RISC microprocessor
J. Montanaro,R. Witek,K. Anne,A.J. Black,Elizabeth M. Cooper,Daniel W. Dobberpuhl,P. Donahue,J. Eno,A. Farell,G. Hoeppner,D. Kruckemyer,Thomas H. Lee,P. Lin,L. Madden,Daniel C. Murray,M. Pearce,S. Santhanam,K. Snyder,R. Stephany,S.C. Thierauf +19 more
- 08 Feb 1996
- Vol. 31, Iss: 11, pp 1703-1714
730
TL;DR: This custom VLSI implementation of a microprocessor architecture delivers 184 Drystone/MIPS at 162 MHz dissipating 0.5 W using an 1.5 V internal supply and Clock generation uses an on-chip PLL with 3.68 MHz input clock to minimize high frequency clock signals on the board.
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Abstract: This paper describes a 160 MHz 500 mW 32 b StrongARM(R) microprocessor designed for low-power, low-cost applications. The chip implements the ARM(R) V4 instruction set and is bus compatible with earlier implementations. The pin interface runs at 3.3 V but the internal power supplies can vary from 1.5 to 2.2 V, providing various options to balance performance and power dissipation. At 160 MHz internal clock speed with a nominal Vdd of 1.65 V, it delivers 185 Dhrystone 2.1 MIPS while dissipating less than 450 mW. The range of operating points runs from 100 MHz at 1.65 V dissipating less than 300 mW to 200 MHz at 2.0 V for less than 900 mW. An on-chip PLL provides the internal clock based on a 3.68 MHz clock input. The chip contains 2.5 million transistors, 90% of which are in the two 16 kB caches. It is fabricated in a 0.35-/spl mu/m three-metal CMOS process with 0.35 V thresholds and 0.25 /spl mu/m effective channel lengths. The chip measures 7.8 mm/spl times/6.4 mm and is packaged in a 144-pin plastic thin quad flat pack (TQFP) package.
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Citations
A new family of semidynamic and dynamic flip-flops with embedded logic for high-performance processors
F. Klass,Chaim Amir,A. Das,Kathirgamar Aingaran,C. Truong,R. Wang,A. Mehta,Raymond A. Heald,G. Yee +8 more
TL;DR: A new family of edge-triggered flip-flops has been developed that has the capability of easily incorporating logic functions with a small delay penalty, and greatly reduces the pipeline overhead.
173
Adaptive mode control: A static-power-efficient cache design
TL;DR: Simulations show that an average of 73% of I-cache lines and 54% of D- caches are put in sleep mode with an average IPC impact of only 1.7%, for 64 KB caches, and this work proposes applying sleep mode only to the data store and not the tag store.
170
23.2 A 1.1nW energy harvesting system with 544pW quiescent power for next-generation implants
Saurav Bandyopadhyay,Patrick P. Mercier,Andrew C. Lysaght,Konstantina M. Stankovic,Anantha P. Chandrakasan +4 more
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TL;DR: This work presents the details of the nanowatt PMU required to power the electronics and focuses on the low-power circuit design techniques needed to realize a nW power converter that is applicable to a broad spectrum of emerging biomedical applications with ultra-low energy-harvesting sources.
Simulation and Analysis of Random Decision Errors in Clocked Comparators
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Designing low-power circuits: practical recipes
TL;DR: The purpose of this paper is to summarize, mainly by way of examples, what in the experience are the most trustful approaches to low-power design, and to provide insights a designer can rely upon when power consumption is a critical constraint.
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A 320 MHz, 1.5 mW@1.35 V CMOS PLL for microprocessor clock generation
TL;DR: A low-power microprocessor clock generator based upon a phase-locked loop (PLL) that is fully integrated onto a 2.2-million transistors microprocessor in a 0.35-/spl mu/m triple-metal CMOS process without the need for external components is described.
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A 300-MHz 64-b quad-issue CMOS RISC microprocessor
B.J. Benschneider,A.J. Black,W.J. Bowhill,S.M. Britton,D.E. Dever,D.R. Donchin,R.J. Dupcak,R.M. Fromm,M.K. Gowan,P.E. Gronowski,M. Kantrowitz,M.E. Lamere,Swati Mehta,J.E. Meyer,R.O. Mueller,A. Olesin,R.P. Preston,Donald A. Priore,S. Santhanam,M.J. Smith,G.M. Wolrich +20 more
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TL;DR: This 300 MHz quad-issue custom VLSI implementation of the Alpha architecture delivers 1200 MIPS, 600 MFLOPS, 341 SPECint92, and 512 SPECfp92 and is packaged in a 499-pin ceramic IPGA.
102
A 320 MHz, 1.5 mW at 1.35 V CMOS PLL for microprocessor clock generation
V. von Kaenel,D. Aebischer,Christian Piguet,Evert Dijkstra +3 more
- 08 Feb 1996
TL;DR: The challenge was to design a phase-locked-loop (PLL) which combines limited jitter, low-supply voltage and low-power consumption.
86
A 433 MHz 64 b quad issue RISC microprocessor
P.E. Gronowski,P. Bannon,R.P. Blake-Campos,G.A. Bouchard,W.J. Bowhill,David A. Carlson,R.W. Castelino,D.R. Donchin,R.M. Fromm,M.K. Gowan,A. Jain,B.J. Loughlin,Swati Mehta,J.E. Meyer,R.O. Mueller,A. Olesin,T.N. Pham,R.P. Preston,Paul I. Rubinfeld +18 more
- 08 Feb 1996
TL;DR: This 9.6 M transistor quad-issue RISC microprocessor achieves greater than 500 SPECint92 (estimated) at 433 MHz and dissipates less than 25 W.
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