Reconfiguring Three-Dimensional Processor Arrays for Fault-Tolerance: Hardness and Heuristic Algorithms

Jiang, Guiyuan; Wu, Jigang; Ha, Yajun; Wang, Yi; Sun, Jizhou

doi:10.1109/tc.2015.2389846

Cited by 14 publications

(1 citation statement)

References 38 publications

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“…Generally, two types of fault tolerance architectures, namely router-based architecture [7][8][9] and switch-based architecture, [10][11][12] are extensively investigated for mesh-connected multiprocessor arrays. Compared with switch-based architecture, router-based architecture is superior in the design of recon¯guration algorithm and utilization of fault-free PEs, but it has disadvantages in hardware cost and power consumption.…”

Section: Introductionmentioning

confidence: 99%

Algorithms for Reconfiguring NoC-Based Fault-Tolerant Multiprocessor Arrays

Jiang

et al. 2019

J CIRCUIT SYST COMP

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This paper investigates the techniques to construct high-quality target processor array (fault-free logical subarray) from a physical array with faulty processing elements (PEs), where a fixed number of spare PEs are pre-integrated that can be used to replace the faulty ones when necessary. A reconfiguration algorithm is successfully developed based on our proposed novel shifting operations that can efficiently select proper spare PEs to replace the faulty ones. Then, the initial target array is further refined by a carefully designed tabu search algorithm. We also consider the problem of constructing a fault-free subarray with given size, instead of the original size, which is often required in energy-efficient MPSoC design. We propose two efficient heuristic algorithms to construct target arrays of given sizes leveraging a sliding window on the physical array. Simulation results show that the improvements of the proposed algorithms over the state of the art are [Formula: see text] and [Formula: see text], in terms of congestion factor and distance factor, respectively, for the case that all faulty PEs can be replaced using the spare ones. For the case of finding [Formula: see text] target array on [Formula: see text] host array, the proposed heuristic algorithm saves the running time up to [Formula: see text] while the solution quality keeps nearly unchanged, in comparison with the baseline algorithms.

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