Low power processor design

Zhou, Yu, Computer Science & Engineering, Faculty of Engineering, UNSW

January 2008

Power consumption is a critical design issue in embedded processors. As part of our low power processor design project, this thesis work aims to reduce power consumption on two typical processor components: Register File (RF), and Arithmetic and Logic Unit (ALU). Register File is one of the most power hungry components in the processor, consuming about 20% of the processor power. The ALU is the working horse in the processor, responsible for almost all basic computing operations. Although ALU does not consume as high power as the register file, we observe that it can be power intensive in terms of power dissipation per silicon area unit and may result in a thermal hot spot in the processor. Existing approaches to reduce power on the register file and ALU are effective. However, most of them either entail extensive hardware design efforts, or require a significant amount of work on post-compilation software code modification. The approaches proposed in this thesis avoid such problems. We only customize the internal structure of the processor components and keep the components’ interface to other system parts intact, so that the customization to a component is transparent to its external hardware design and no modification/alteration to other hardware components or to the software code is required. This customization strategy is well suitable to our whole low power processor design project and can be applied to any customization of an existing system for a given application. We have applied our customization approaches to a set of benchmarks in a variety of application domains. Our experimental results show that the power savings on register file are in a range from 18.8% to 45.5%, an average of 29.7% register file power can be saved. For the arithmetic and logic unit, the power savings are from 43.5% to 49.6% and the average saving is 46.9% as compared to the original designs. We also combine the customization of both the ALU and the register file. With the customizing of the ALU and the register file simultaneously, the processor power consumption can be reduced from 3.9% to 10.1%; on average, 6.44% processor power can be saved. Most importantly, the power saving achievement is at the cost of neither hardware complexity nor processor performance, and the implementation is extremely straightforward and can be easily incorporated into a processor design environment, such as ASIPMeister (a design tool, to automatically generate a VHDL model for application specificinstruction set processors) used in our research.

Register files

Low power

ALU

Low power processor design

Zhou, Yu, Computer Science & Engineering, Faculty of Engineering, UNSW

January 2008

Power consumption is a critical design issue in embedded processors. As part of our low power processor design project, this thesis work aims to reduce power consumption on two typical processor components: Register File (RF), and Arithmetic and Logic Unit (ALU). Register File is one of the most power hungry components in the processor, consuming about 20% of the processor power. The ALU is the working horse in the processor, responsible for almost all basic computing operations. Although ALU does not consume as high power as the register file, we observe that it can be power intensive in terms of power dissipation per silicon area unit and may result in a thermal hot spot in the processor. Existing approaches to reduce power on the register file and ALU are effective. However, most of them either entail extensive hardware design efforts, or require a significant amount of work on post-compilation software code modification. The approaches proposed in this thesis avoid such problems. We only customize the internal structure of the processor components and keep the components’ interface to other system parts intact, so that the customization to a component is transparent to its external hardware design and no modification/alteration to other hardware components or to the software code is required. This customization strategy is well suitable to our whole low power processor design project and can be applied to any customization of an existing system for a given application. We have applied our customization approaches to a set of benchmarks in a variety of application domains. Our experimental results show that the power savings on register file are in a range from 18.8% to 45.5%, an average of 29.7% register file power can be saved. For the arithmetic and logic unit, the power savings are from 43.5% to 49.6% and the average saving is 46.9% as compared to the original designs. We also combine the customization of both the ALU and the register file. With the customizing of the ALU and the register file simultaneously, the processor power consumption can be reduced from 3.9% to 10.1%; on average, 6.44% processor power can be saved. Most importantly, the power saving achievement is at the cost of neither hardware complexity nor processor performance, and the implementation is extremely straightforward and can be easily incorporated into a processor design environment, such as ASIPMeister (a design tool, to automatically generate a VHDL model for application specificinstruction set processors) used in our research.

Register files

Low power

ALU

Simulation distribuée de réseaux de files d'attente /

Rakotoarisoa, Hery Michel.

January 1900

Th. doct.-ing.--Informatique--Nice-Sophia Antipolis, 1994. / 1994 d'après la déclaration du dépôt légal. Résumé en français. Bibliogr. p. 125-131.

Contribution à l'étude d'un analyseur de modèles à réseaux de files d'attente : algorithmes de calcul et applications.

Merle, Didier,

January 1900

Th. doct.-ing.--Nancy, I. N. P. L., 1978. / Rés. de la th. _ 3 f.

Synthesizing Uncorrelated Drive Files for MIMO Transmissibility Measurements on Road Simulators

Deshmukh, Shounak

12 September 2016

No description available.

Mechanical Engineering

Mechanics

Drive Files

Synthesized Drive Files

Uncorrelated Drive Files

Four Axis Road Simulator

MIMO Transmissibility

Change management and synchronization of local and shared versions of a controlled vocabulary

Oliver, Diane Elizabeth.

January 1900

Thesis (Ph.D)--Stanford University, 2000. / Title from pdf t.p. (viewed April 3, 2002). "August 2000." "Adminitrivia V1/Prg/20000831"--Metadata.

Cutting efficiency of endodontic files in linear motion a thesis submitted in partial fulfillment ... endodontics ... /

Santiago, Rafael.

January 1984

Thesis (M.S.)--University of Michigan, 1984.

The stainless steel endodontic file its use in obturation of difficult root canals : a dissertation [sic] submitted in partial fulfillment ... endodontics and radiology ... /

Sampeck, Adrian J.

January 1961

Thesis (M.S.)--University of Michigan, 1961.

A comparison of the Orban and Bunting periodontal files a thesis presented in partial fulfillment ... in dental hygiene education ... /

Burke, Sherry Wells.

January 1969

Thesis (M.S.)--University of Michigan, 1969.

Authority control and its influence on recall and precision in an online bibliographic catalog

Garrett, LeAnn.

January 1997

Thesis (Ph. D.)--University of Hawaii, 1997. / eContent provider-neutral record in process. Description based on print version record.