Fault tolerant, radiation hard, high performance digital signal processor (for spacecraft receiver)

9th IEEE/AIAA/NASA Conference on Digital Avionics Systems Pub Date : 1990-10-15 DOI:10.1109/DASC.1990.111334

E. Holmann, I. Linscott, M. J. Maurer, G. L. Tyler, V. Libby

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引用次数: 2

Abstract

An architecture has been developed for a high-performance VLSI digital signal processor that is highly reliable, fault-tolerant, and radiation-hard. The signal processor, part of a spacecraft receiver designed to support uplink radio science experiments at the outer planets, organizes the connections between redundant arithmetic resources, register files, and memory through a shuffle exchange communication network. The configuration of the network and the state of the processor resources are all under microprogram control, which both maps the resources according to algorithmic needs and reconfigures the processing should a failure occur. In addition, the microprogram is reloadable through the uplink to accommodate changes in the science objectives throughout the course of the mission. The processor will be implemented with silicon compiler tools, and its design will be verified through silicon compilation simulation at all levels from the resources to full functionality. By blending reconfiguration with redundancy the processor implementation is fault-tolerant and reliable, and possesses the long expected lifetime needed for a spacecraft mission to the outer planets.<>

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容错、抗辐射、高性能数字信号处理器(用于航天器接收机)

针对高性能VLSI数字信号处理器，提出了一种高可靠、高容错、高抗辐射的结构。信号处理器是航天器接收器的一部分，旨在支持外行星的上行无线电科学实验，通过随机交换通信网络组织冗余算术资源，寄存器文件和存储器之间的连接。网络的配置和处理器资源的状态都在微程序控制之下，微程序根据算法需要映射资源，并在发生故障时重新配置处理。此外，微程序可以通过上行链路重新加载，以适应整个任务过程中科学目标的变化。处理器将使用硅编译器工具实现，其设计将通过从资源到全功能的各个层面的硅编译仿真来验证。通过将重构与冗余相结合，该处理器实现具有容错和可靠的特点，并具有航天器到外行星执行任务所需的较长的预期寿命

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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9th IEEE/AIAA/NASA Conference on Digital Avionics Systems

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