High Throughput Asynchronous NoC Design under High Process Variation

Asynchronous switching is proposed as a robust design to mitigate the impact of process variation in Network on Chip (NoC). Circuit analysis is used to evaluate the influence of process variation on both synchronous and asynchronous designs. The impact of process variation is evaluated on different...

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Published in:Integration (Amsterdam) 2015-03, Vol.49, p.1-13
Main Authors: Ezz-Eldin, Rabab, El-Moursy, Magdy A., Hamed, Hesham F.A.
Format: Article
Language:English
Subjects:
Asynchronous design
Clock skew
Clocks
Delay
Design engineering
Interconnect
Interconnections
Network on Chip
Networks
NoC topologies
Process variation
Switching theory
Synchronous
Synchronous design
System on chip
Topology
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description Asynchronous switching is proposed as a robust design to mitigate the impact of process variation in Network on Chip (NoC). Circuit analysis is used to evaluate the influence of process variation on both synchronous and asynchronous designs. The impact of process variation is evaluated on different NoC topologies. Network on chip interconnects and clock distribution network are considered under process variation with the advance in technology. The variation in logic and interconnect are included to evaluate the delay, throughput and leakage power variation with different NoC topologies. In addition, the delay and throughput variation are evaluated for clock distribution network. For asynchronous NoC design, the throughput negligibly decreases under high process variation conditions in different NoC topologies. The throughput variation for synchronous design in all topologies rapidly decreases by up to 25% at the same variation conditions. •Synchronous and asynchronous designes are provided for NoC.•The throughput of synchronous design rapidly reduces as compared to nominal values for different technologies.•The throughput of asynchronous designe under process variation almost remains the same as compared to nominal values for different topologies
doi_str_mv 10.1016/j.vlsi.2014.10.006
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subjects Asynchronous design
Clock skew
Clocks
Delay
Design engineering
Interconnect
Interconnections
Network on Chip
Networks
NoC topologies
Process variation
Switching theory
Synchronous
Synchronous design
System on chip
Topology
title High Throughput Asynchronous NoC Design under High Process Variation
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