A fault-tolerance strategy for an FPGA-based multi-stage interconnection network in a multi-sensor system for space application

Proceedings 2001 IEEE International Symposium on Defect and Fault Tolerance in VLSI Systems Pub Date : 2001-10-24 DOI:10.1109/DFTVS.2001.966770

M. Alderighi, F. Casini, S. D'Angelo, D. Salvi, G. Sechi

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引用次数: 4

Abstract

Space research requires increasingly huge amounts of scientific data. Next generation satellites will have on-board supercomputing capabilities to perform efficient information processing and overcome the possible limit imposed by communication bandwidth to ground receiving stations. They will also have to survive even longer term missions; thus reliability and fault tolerance will be a major concern, to cope with radiation induced faults. Flexibility also emerges as a desirable requisite for on-board processing system to implement new functionalities and run different algorithms for the ongoing mission. The trend is towards multiprocessor architecture in which processing nodes and memories are connected through high bandwidth interconnection networks. The paper presents a fault-tolerance strategy for an FPGA implementation of a redundant multistage interconnection network (MIN), for a space multi-sensor system. The mechanism is endowed with fault diagnosis ability which allows one to exploit MIN intrinsic reconfiguration capabilities, as well as the reprogrammability of SRAM-based FPGAs.

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空间多传感器系统中基于fpga的多级互连网络容错策略

空间研究需要越来越多的科学数据。下一代卫星将具有机载超级计算能力，以执行有效的信息处理，并克服通信带宽对地面接收站施加的可能限制。它们还必须在更长期的任务中存活下来;因此，可靠性和容错性将是主要关注的问题，以应对辐射引起的故障。灵活性也是机载处理系统实现新功能和为正在进行的任务运行不同算法的理想条件。多处理器架构的发展趋势是通过高带宽互连网络连接处理节点和存储器。针对空间多传感器系统，提出了一种基于FPGA的冗余多级互连网络(MIN)容错策略。该机制具有故障诊断能力，使人们能够利用MIN固有的重构能力，以及基于sram的fpga的可重编程性。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Proceedings 2001 IEEE International Symposium on Defect and Fault Tolerance in VLSI Systems

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