An Asynchronous Power Aware and Adaptive NoC Based Circuit

An Asynchronous Power Aware and Adaptive NoC Based Circuit

In complex embedded applications, optimisation and adaptation of both dynamic and leakage power have become an issue at SoC grain. A fully power-aware globally-asynchronous locally-synchronous network-on-chip (NoC) circuit is presented in this paper. Network-on-chip architecture combined with a glob...

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Veröffentlicht in:IEEE journal of solid-state circuits 2009-04, Vol.44 (4), p.1167-1177
Hauptverfasser: Beigne, E., Clermidy, F., Lhermet, H., Miermont, S., Thonnart, Y., Xuan-Tu Tran, Valentian, A., Varreau, D., Vivet, P., Popon, X., Lebreton, H.
Format: Artikel
Sprache:eng
Schlagworte:
Applied sciences
Circuit properties
Circuits
Communication system control
DC-DC converters
Delay
Design. Technologies. Operation analysis. Testing
DVFS
dynamic power
Dynamic voltage scaling
Dynamics
Electric potential
Electric, optical and optoelectronic circuits
Electrical engineering. Electrical power engineering
Electronic circuits
Electronic equipment and fabrication. Passive components, printed wiring boards, connectics
Electronics
Energy consumption
Exact sciences and technology
Frequency
GALS
Integrated circuits
leakage power
Network-on-a-chip
Network-on-chip
Optimization
Power consumption
Power control
Power electronics, power supplies
Semiconductor electronics. Microelectronics. Optoelectronics. Solid state devices
Signal convertors
super cut-off
Synchronous
Throughput
Vdd-hopping
Voltage
Voltage control
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Beschreibung
Zusammenfassung:In complex embedded applications, optimisation and adaptation of both dynamic and leakage power have become an issue at SoC grain. A fully power-aware globally-asynchronous locally-synchronous network-on-chip (NoC) circuit is presented in this paper. Network-on-chip architecture combined with a globally-asynchronous locally-synchronous paradigm is a natural enabler for DVFS mechanisms. The circuit is arranged around an asynchronous network-on-chip providing scalable communication and a 17 Gb/s throughput while automatically reducing its power consumption by activity detection. Both dynamic and static power consumptions are globally reduced using adaptive design techniques applied locally for each synchronous NoC units. No fine control software is required during voltage and frequency scaling. Power control is localized and a minimal latency cost is observed.
ISSN:0018-9200
1558-173X
DOI:10.1109/JSSC.2009.2014206