The MARUTI hard real-time operating system

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The MARUTI hard real-time operating system

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ACM SIGOPS Operating Systems Review archive
Volume 23 , Issue 3 (July 1989) table of contents

Pages: 90 - 105

Year of Publication: 1989

ISSN:0163-5980

Authors

S. Levi	Department of Computer Science, University of Maryland, College Park, MD
S. K. Tripathi	Department of Computer Science, University of Maryland, College Park, MD
S. D. Carson	Department of Computer Science, University of Maryland, College Park, MD
A. K. Agrawala	Department of Computer Science, University of Maryland, College Park, MD

Publisher

ACM New York, NY, USA

Bibliometrics

Downloads (6 Weeks): 8, Downloads (12 Months): 22, Citation Count: 9

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abstract cited by index terms collaborative colleagues

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ABSTRACT

The MARUTI operating system is designed to support real-time applications on a variety of hardware systems. The kernel supports objects as primitive entities, and provides a communication mechanism that allows transparent distribution in networked systems. Fault tolerance is provided through replication and consistency-control mechanisms. Most importantly, MARUTI supports guaranteed-service scheduling, in which jobs that are accepted by the system are verified to satisfy general time constraints.Guaranteed-service scheduling means that, given a job with a set of service requirements and time constraints, the system automatically verifies the schedulability of each component of the job with respect to the job's constraints and those of other jobs in the system. These time constraints include those that govern interrupt processing, which allows the MARUTI approach to succeed where tess rigorous approaches do not. The result is that MARUTI applications can be executed in a predictable, deterministic fashion.

CITED BY 9

	David Langan, EOS: an object-oriented operating system for embedded real-time applications, Proceedings of the 1993 ACM conference on Computer science, p.60-65, February 16-18, 1993, Indianapolis, Indiana, United States
	Vivek Nirkhe , William Pugh, Partial evaluation of high-level imperative programming languages with applications in hard real-time systems, Proceedings of the 19th ACM SIGPLAN-SIGACT symposium on Principles of programming languages, p.269-280, January 19-22, 1992, Albuquerque, New Mexico, United States
	Swaminathan Natarajan , Wei Zhao, Issues in Building Dynamic Real-Time Systems, IEEE Software, v.9 n.5, p.16-21, September 1992
	Sheng-Tzong Cheng , Shyh-In Hwang, Optimal Real-Time Scheduling with Minimal Rejections andMinimal Finishing Time, Real-Time Systems, v.20 n.3, p.229-253, May 2001
	Victor B. Lortz , Kang G. Shin , Jinho Kim, MDARTS: A Multiprocessor Database Architecture for Hard Real-Time Systems, IEEE Transactions on Knowledge and Data Engineering, v.12 n.4, p.621-644, July 2000
	K. Subramani, An Analysis of Totally Clairvoyant Scheduling, Journal of Scheduling, v.8 n.2, p.113-133, April 2005
	Rex E. Gantenbein, An annotated bibliography of dependable distributed computing, ACM SIGOPS Operating Systems Review, v.26 n.2, p.60-81, April 1992
	K. Subramani , Kiran Yellajyosula, On the design and implementation of a shared memory dispatcher for partially clairvoyant schedulers, International Journal of Parallel Programming, v.36 n.4, p.386-411, August 2008
	K. Subramani, Optimal Length Resolution Refutations of Difference Constraint Systems, Journal of Automated Reasoning, v.43 n.2, p.121-137, August 2009