Energy-efficient processor design using multiple clock domains with dynamic voltage and frequency scaling

Energy-efficient processor design using multiple clock domains with dynamic voltage and frequency scaling

As clock frequency increases and feature size decreases, clock distribution and wire delays present a growing challenge to the designers of singly-clocked, globally synchronous systems. We describe an alternative approach, which we call a multiple clock domain (MCD) processor, in which the chip is d...

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Bibliographic Details
Published in:Proceedings Eighth International Symposium on High Performance Computer Architecture pp. 29 - 40
Main Authors: Semeraro, G., Magklis, G., Balasubramonian, R., Albonesi, D.H., Dwarkadas, S., Scott, M.L.
Format: Conference Proceeding
Language:English
Published: IEEE 2002
Subjects:
Clocks
Costs
Delay
Dynamic voltage scaling
Energy efficiency
Frequency conversion
Frequency synchronization
Potential energy
Process design
Wire
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Summary:As clock frequency increases and feature size decreases, clock distribution and wire delays present a growing challenge to the designers of singly-clocked, globally synchronous systems. We describe an alternative approach, which we call a multiple clock domain (MCD) processor, in which the chip is divided into several clock domains, within which independent voltage and frequency scaling can be performed. Boundaries between domains are chosen to exploit existing queues, thereby minimizing inter-domain synchronization costs. We propose four clock domains, corresponding to the front end , integer units, floating point units, and load-store units. We evaluate this design using a simulation infrastructure based on SimpleScalar and Wattch. In an attempt to quantify potential energy savings independent of any particular on-line control strategy, we use off-line analysis of traces from a single-speed run of each of our benchmark applications to identify profitable reconfiguration points for a subsequent dynamic scaling run. Using applications from the MediaBench, Olden, and SPEC2000 benchmark suites, we obtain an average energy-delay product improvement of 20% with MCD compared to a modest 3% savings from voltage scaling a single clock and voltage system.
ISBN:0769515258
9780769515250
ISSN:1530-0897
2378-203X
DOI:10.1109/HPCA.2002.995696