An Ω(√ log log n) lower bound for routing in optical networks

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An Ω(√ log log n) lower bound for routing in optical networks

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ACM Symposium on Parallel Algorithms and Architectures archive
Proceedings of the sixth annual ACM symposium on Parallel algorithms and architectures table of contents

Cape May, New Jersey, United States

Pages: 147 - 156

Year of Publication: 1994

ISBN:0-89791-671-9

Authors

Leslie Ann Goldberg
Mark Jerrum
Philip D. MacKenzie

Sponsors

SIGACT: ACM Special Interest Group on Algorithms and Computation Theory
SIGARCH: ACM Special Interest Group on Computer Architecture
European Comp Soc : European Computer Society

Publisher

ACM New York, NY, USA

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Downloads (6 Weeks): 1, Downloads (12 Months): 6, Citation Count: 5

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ABSTRACT

Optical communication is likely to significantly speed up parallel computation because the vast bandwidth of the optical medium can be divided to produce communication networks of very high degree. However, the problem of contention in high-degree networks makes the routing problem in these networks theoretically (and practically) difficult. In this paper we examine Valiant's h-relation routing problem, which is a fundamental problem in the theory of parallel computing. The h-relation routing problem arises both in the direct implementation of specific parallel algorithms on distributed-memory machines and in the general simulation of shared memory models such as the PRAM on distributed-memory machines. In an h -relation routing problem each processor has up to h messages that it wishes to send to other processors and each processor is the destination of at most h messages. We present a lower bound for routing an h-relation (for any h > 1) on a complete optical network of size n. Our lower bound applies to any randomized distributed algorithm for this task. Specifically. we show that the expected number of communication steps required to route an arbitrary h-relation is Wh+loglogn . This is the first known lower bound for this problem which does not restrict the class of algorithms under consideration.

REFERENCES

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CITED BY 5

	Philip D. MacKenzie, Lower bounds for randomized exclusive write PRAMs, Proceedings of the seventh annual ACM symposium on Parallel algorithms and architectures, p.254-263, June 24-26, 1995, Santa Barbara, California, United States
	Dannie Durand , Ravi Jain , David Tseytlin, Applying randomized edge coloring algorithms to distributed communication: an experimental study, Proceedings of the seventh annual ACM symposium on Parallel algorithms and architectures, p.264-274, June 24-26, 1995, Santa Barbara, California, United States
	Xiaotie Deng , Patrick Dymond, On multiprocessor system scheduling, Proceedings of the eighth annual ACM symposium on Parallel algorithms and architectures, p.82-88, June 24-26, 1996, Padua, Italy
	Dannie Durand , Ravi Jain , David Tseytlin, Parallel I/O scheduling using randomized, distributed edge coloring algorithms, Journal of Parallel and Distributed Computing, v.63 n.6, p.611-618, June 2003
	Adnan Agbaria , Yosi Ben-Asher , Ilan Newman, Communication-processor tradeoffs in limited resources PRAM, Proceedings of the eleventh annual ACM symposium on Parallel algorithms and architectures, p.74-82, June 27-30, 1999, Saint Malo, France