The reliability of networks-on-chip (NoC) is threatened by low yield and device wearout in aggressively scaled technology nodes. We propose ReliNoC, a network-on-chip architecture which can withstand failures, while maintaining not only basic connectivity, but also quality-of-service support based on packet priorities. Our network leverages a dual physical channel switch architecture which removes the control overhead of virtual channels (VCs) and utilizes the inherent redundancy within the 2-channel switch to provide spares for faulty elements. Experimental results show that ReliNoC provides 1.5 to 3 times better network physical connectivity in presence of several faults, and reduces the latency of both high and low priority traffic by 30 to 50%, compared to a traditional VC architecture. Moreover, it can tolerate up to 50 faults within an 8×8 mesh at only 10 and 40% latency overhead on control and data packets for PARSEC traces. Synthesis results show that our reliable architecture incurs only 13% area overhead on the baseline 2-channel switch.
ReliNoC: A reliable network for priority-based on-chip communication / Kakoee M.R. ; Bertacco V. ; Benini L.. - STAMPA. - (2011), pp. 1-6. (Intervento presentato al convegno Design, Automation & Test in Europe Conference & Exhibition (DATE), 2011 tenutosi a Grenoble, France nel 14-18 March 2011) [10.1109/DATE.2011.5763112].
ReliNoC: A reliable network for priority-based on-chip communication
KAKOEE, MOHAMMAD REZA;BENINI, LUCA
2011
Abstract
The reliability of networks-on-chip (NoC) is threatened by low yield and device wearout in aggressively scaled technology nodes. We propose ReliNoC, a network-on-chip architecture which can withstand failures, while maintaining not only basic connectivity, but also quality-of-service support based on packet priorities. Our network leverages a dual physical channel switch architecture which removes the control overhead of virtual channels (VCs) and utilizes the inherent redundancy within the 2-channel switch to provide spares for faulty elements. Experimental results show that ReliNoC provides 1.5 to 3 times better network physical connectivity in presence of several faults, and reduces the latency of both high and low priority traffic by 30 to 50%, compared to a traditional VC architecture. Moreover, it can tolerate up to 50 faults within an 8×8 mesh at only 10 and 40% latency overhead on control and data packets for PARSEC traces. Synthesis results show that our reliable architecture incurs only 13% area overhead on the baseline 2-channel switch.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.
