Microarchitectural Level Power Analysis and Optimization in Single Chip Parallel Computers

Microarchitectural Level Power Analysis and Optimization in Single Chip Parallel Computers (2004)

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by Joseph G. Tront , Priyadarshini Ramachandran , Priyadarshini Ramachandran , James M. Baker , Committee Chair

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BibTeX

@TECHREPORT{Tront04microarchitecturallevel,
    author = {Joseph G. Tront and Priyadarshini Ramachandran and Priyadarshini Ramachandran and James M. Baker and Committee Chair},
    title = {Microarchitectural Level Power Analysis and Optimization in Single Chip Parallel Computers},
    institution = {},
    year = {2004}
}

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Abstract

As device technologies migrate into Deep Submicron (DSM) feature sizes, highperformance power-efficient computer architectures that keep pace with improving technologies need to be explored. Technology scaling increases the effects of wire latencies, inductive effects, noise and crosstalk in on-chip communication, limiting the performance of DSM designs. Power efficient performance gains from Instruction Level Parallelism (ILP) are reaching a limit. Single-Chip Parallel Computers are promising solutions to the DSM design challenges and the performance limitations of ILP. These systems are explicitly modular architectures that efficiently support Thread Level Parallelism (TLP) while avoiding global signals and shared resources. Microarchitectural level power analysis is required for evaluating the feasibility of newly conceived architectures in terms of power dissipation and energy efficiency. Accounting for power in the early stages of design shortens the time-to-market due to reduced design iteration times. Power optimizations at the architectural level can yield large power savings. This thesis proposes a microarchitectural level power estimation and

Citations

843	Wattch: A Framework for Architectural-Level Power Analysis and Optimizations - Brooks, Tiwari, et al. - 2000
393	SimpleScalar: An Infrastructure for Computer System Modeling - Austin, Larson, et al.
324	The future of wires - Ho, Mai, et al. - 2001
226	Pipeline Gating: Speculation Control For Energy Reduction - Manne, Klauser, et al. - 1998
190	Energy dissipation in general purpose microprocessors - Gonzalez, Horowitz - 1996
129	Gated-Vdd: a circuit technique to reduce leakage - Powell - 2000
117	Multiple-banked Register File Architectures - Cruz, Gonzlez, et al. - 2000
114	How Multimedia Workloads Will Change Processor Design - Diefendorff, Dubey - 1997
112	A Static Power Model for Architects - Butts, Sohi - 2000
105	Getting to the bottom of deep submicron - Sylvester, Keutzer - 1998
68	The Message-Driven Processor: A Multicomputer Processing Node with Efficient Mechanisms - Dally, Fiske, et al. - 1992
60	Low power digital CMOS design - Chandrakasan, Brodersen - 1995
52	Low-power logic styles: CMOS versus pass-transistor logic - Zimmermann, Fichtner - 1997
50	et al., “Baring it all to software: RAW machines - Waingold - 1997
33	Lowering power consumption in clock by using globally asynchronous locally synchronous design style - Hemani, Meincke, et al. - 1999
33	Thermal performance challenges from silicon to systems - Vishwanath, Wakharkar, et al. - 2000
31	A Power Model for Routers: Modeling Alpha 21364 - Wang, Peh, et al. - 2003
29	Getting to the Bottom of Deep Submicron II: a global wiring paradigm - Sylvester, Keutzer - 1999
28	Practical Low Power Digital VLSI Design - Yeap - 1998
26	VLSI architecture: past, present, and future - Dally, Lacy - 1999
24	Rethinking deep-submicron circuit design - Sylvester, Keutzer - 1999
24	Transistor Sizing for Low Power CMOS Circuits - Borah, Owens, et al. - 1996
19	Orion: a power-performance simulator for interconnection networks - Wang, Zhu, et al. - 2002
12	System level leakage reduction considering the interdependence of temperature and leakage - He, Liao, et al.
10	Shrinking devices put the squeeze on system packaging - Small - 1994
10	Design for Reliability: The Major Challenge for VLSI - Yang, Chern - 1993
9	Managing wire scaling: A circuit perspective - Ho, Mai, et al. - 2003
9	Split register file architectures for inherently lower power microprocessors - Zyuban, Kogge - 1998
7	Cooling and power consideration for semiconductors into the next century - Belady - 2001
7	Tools and Methodologies for Low Power Design - Frenkil - 1997
7	Leakage in nanoscale technologies: Mechanisms, impact and design considerations - Agarwal, Kim, et al. - 2004
7	Balancing performance, area, and power in an on-chip network - Gold - 2003
6	Hotleakage: An architectural, temperature-aware model of subthreshold and gate leakage - Zhang, Parikh, et al. - 2003
5	Gene Team, “Blue Gene: A Vision for Protein Science using a Petaflop Supercomputer - Blue - 2001
5	High-Throughput, Low-Memory Applications on the Pica Architecture - unknown authors - 1994
5	et al., “Reducing Power - Tiwari - 1998
4	et al, “The design and use of SimplePower: A cycleaccurate energy estimation tool - Ye - 2000
3	BSIM3v3.1 SPICE MOS device models - Berkeley - 1997
2	Jha and Sujit Dey, High level Power analysis and optimization - Raghunathan, Niraj - 1998
2	et al, “The case for a single chip multiprocessor - Olukomn - 1996
2	et al, “Scmp: A single-chip message-passing parallel computer - Jr - 1989
2	Memory-Intensive Benchmarks: IRAM vs. Cache-Based Machines - Gaeke - 2002
1	Power analysis and optimization: spanning the levels of abstraction - Nebel, Sproch, et al. - 1997