Please use this identifier to cite or link to this item: https://hdl.handle.net/20.500.14279/4111
Title: A Dynamically Adjusting Gracefully Degrading Link-level Fault-tolerant Mechanism for NoCs
Authors: Vitkovskiy, Arseniy 
Nicopoulos, Chrysostomos 
Soteriou, Vassos 
Major Field of Science: Engineering and Technology
Field Category: Electrical Engineering - Electronic Engineering - Information Engineering
Keywords: Routers (Computer networks);Computer architecture;Computer science;Networks on a chip;Algorithms;Microprocessors;Fault tolerance (Engineering)
Issue Date: Aug-2012
Source: IEEE Transactions on Computer-Aided Design of Integrated Circuits and Systems, 2012, vol. 31, no. 8, pp. 1235 - 1248
Volume: 31
Issue: 8
Start page: 1235
End page: 1248
Journal: IEEE Transactions on Computer-Aided Design of Integrated Circuits and Systems 
Abstract: The rapid scaling of silicon technology has enabled massive transistor integration densities. Nanometer feature sizes, however, are marred by increasing variability and susceptibility to wear-out. Billion-transistor designs, such as chip multiprocessors (CMPs), are especially vulnerable to defects. CMPs rely on a network-on-chip for all their communication needs. A single link failure within this on-chip fabric can impede, halt, or even deadlock, intertile communication, which can render the entire chip multiprocessor useless. In this paper, we present a technique capable of handling very large numbers of permanent wire failures that occur in parallel links either at manufacture-time or at runtime (dynamically). As opposed to marking an entire parallel link as faulty, whenever some wires fail, the proposed methodology employs these partially-faulty links (PFLs) to continue the transfer of information-albeit at a gracefully degraded mode-in order to maintain network connectivity. Furthermore, the presented technique can designate PFLs as fully-faulty when several wires fail, by utilizing appropriate routing algorithms that bypass nonoperational links, while still maintaining load-balance in the vicinity of PFLs. The proposed scheme employs architectural support within the on-chip routers to detect link failures and enable reconfiguration at the granularity of individual wires. Hardware synthesis confirms the low-cost nature of the proposed architecture, and full-system simulations using both synthetic network traffic and real workloads demonstrate its efficacy
URI: https://hdl.handle.net/20.500.14279/4111
ISSN: 02780070
DOI: 10.1109/TCAD.2012.2188801
Rights: © Copyright 2012 IEEE
Type: Article
Affiliation : Cyprus University of Technology 
Publication Type: Peer Reviewed
Appears in Collections:Άρθρα/Articles

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