Autonomous Fault Emulation: A New FPGA-Based Acceleration System for Hardness Evaluation

The appearance of nanometer technologies has produced a significant increase of integrated circuit sensitivity to radiation, making the occurrence of soft errors much more frequent, not only in applications working in harsh environments, like aerospace circuits, but also for applications working at...

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Published in:IEEE transactions on nuclear science 2007-02, Vol.54 (1), p.252-261
Main Authors: Lopez-Ongil, C., Garcia-Valderas, M., Portela-Garcia, M., Entrena, L.
Format: Article
Language:English
Subjects:
Acceleration
Aircraft components
Application specific integrated circuits
Autonomous
Circuit faults
Circuits
Earth
Emulation
Fault emulation
fault injection
Fault tolerance
Faults
Field programmable gate arrays
FPGA
Hardness
Integrated circuit technology
Integrated circuits
Radiation hardening
reliability testing
SEU
Soft errors
Studies
Very large scale integration
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cited_by cdi_FETCH-LOGICAL-c458t-29d385a6837166430284346ebd244b7fa4d62ef055361da33990e31f9ffab5793
cites cdi_FETCH-LOGICAL-c458t-29d385a6837166430284346ebd244b7fa4d62ef055361da33990e31f9ffab5793
container_end_page 261
container_issue 1
container_start_page 252
container_title IEEE transactions on nuclear science
container_volume 54
creator Lopez-Ongil, C.
Garcia-Valderas, M.
Portela-Garcia, M.
Entrena, L.
description The appearance of nanometer technologies has produced a significant increase of integrated circuit sensitivity to radiation, making the occurrence of soft errors much more frequent, not only in applications working in harsh environments, like aerospace circuits, but also for applications working at the earth surface. Therefore, hardened circuits are currently demanded in many applications where fault tolerance was not a concern in the very near past. To this purpose, efficient hardness evaluation solutions are required to deal with the increasing size and complexity of modern VLSI circuits. In this paper, a very fast and cost effective solution for SEU sensitivity evaluation is presented. The proposed approach uses FPGA emulation in an autonomous manner to fully exploit the FPGA emulation speed. Three different techniques to implement it are proposed and analyzed. Experimental results show that the proposed Autonomous Emulation approach can reach execution rates higher than one million faults per second, providing a performance improvement of two orders of magnitude with respect to previous approaches. These rates give way to consider very large fault injection campaigns that were not possible in the past
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subjects Acceleration
Aircraft components
Application specific integrated circuits
Autonomous
Circuit faults
Circuits
Earth
Emulation
Fault emulation
fault injection
Fault tolerance
Faults
Field programmable gate arrays
FPGA
Hardness
Integrated circuit technology
Integrated circuits
Radiation hardening
reliability testing
SEU
Soft errors
Studies
Very large scale integration
title Autonomous Fault Emulation: A New FPGA-Based Acceleration System for Hardness Evaluation
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