Response-time analysis for mixed criticality systems

S. K. Baruah; A. Burns; R. I. Davis

doi:10.1109/RTSS.2011.12

Response-time analysis for mixed criticality systems

S. K. Baruah
, A. Burns
, R. I. Davis

Department of Computer Science & Engineering

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

321 Scopus citations

Abstract

Many safety-critical embedded systems are subject to certification requirements. However, only a subset of the functionality of the system may be safety-critical and hence subject to certification; the rest of the functionality is non safety-critical and does not need to be certified, or is certified to a lower level. The resulting mixed criticality system offers challenges both for static schedulability analysis and run-time monitoring. This paper considers a novel implementation scheme for fixed priority uniprocessor scheduling of mixed criticality systems. The scheme requires that jobs have their execution times monitored (as is usually the case in high integrity systems). An optimal priority assignment scheme is derived and sufficient response-time analysis is provided. The new scheme formally dominates those previously published. Evaluations illustrate the benefits of the scheme.

Original language	English
Title of host publication	Proceedings - 2011 32nd IEEE Real-Time Systems Symposium, RTSS 2011
Pages	34-43
Number of pages	10
DOIs	https://doi.org/10.1109/RTSS.2011.12
State	Published - 2011
Event	2011 32nd IEEE Real-Time Systems Symposium, RTSS 2011 - Vienna, Austria Duration: Nov 29 2011 → Dec 2 2011

Publication series

Name	Proceedings - Real-Time Systems Symposium
ISSN (Print)	1052-8725

Conference

Conference	2011 32nd IEEE Real-Time Systems Symposium, RTSS 2011
Country/Territory	Austria
City	Vienna
Period	11/29/11 → 12/2/11

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10.1109/RTSS.2011.12

Cite this

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title = "Response-time analysis for mixed criticality systems",

abstract = "Many safety-critical embedded systems are subject to certification requirements. However, only a subset of the functionality of the system may be safety-critical and hence subject to certification; the rest of the functionality is non safety-critical and does not need to be certified, or is certified to a lower level. The resulting mixed criticality system offers challenges both for static schedulability analysis and run-time monitoring. This paper considers a novel implementation scheme for fixed priority uniprocessor scheduling of mixed criticality systems. The scheme requires that jobs have their execution times monitored (as is usually the case in high integrity systems). An optimal priority assignment scheme is derived and sufficient response-time analysis is provided. The new scheme formally dominates those previously published. Evaluations illustrate the benefits of the scheme.",

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AU - Baruah, S. K.

AU - Burns, A.

AU - Davis, R. I.

PY - 2011

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AB - Many safety-critical embedded systems are subject to certification requirements. However, only a subset of the functionality of the system may be safety-critical and hence subject to certification; the rest of the functionality is non safety-critical and does not need to be certified, or is certified to a lower level. The resulting mixed criticality system offers challenges both for static schedulability analysis and run-time monitoring. This paper considers a novel implementation scheme for fixed priority uniprocessor scheduling of mixed criticality systems. The scheme requires that jobs have their execution times monitored (as is usually the case in high integrity systems). An optimal priority assignment scheme is derived and sufficient response-time analysis is provided. The new scheme formally dominates those previously published. Evaluations illustrate the benefits of the scheme.

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U2 - 10.1109/RTSS.2011.12

DO - 10.1109/RTSS.2011.12

M3 - Conference contribution

AN - SCOPUS:84856523560

SN - 9780769545912

T3 - Proceedings - Real-Time Systems Symposium

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EP - 43

BT - Proceedings - 2011 32nd IEEE Real-Time Systems Symposium, RTSS 2011

T2 - 2011 32nd IEEE Real-Time Systems Symposium, RTSS 2011

Y2 - 29 November 2011 through 2 December 2011

ER -

Response-time analysis for mixed criticality systems

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