An improved primal simplex variant for pure processing networks

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An improved primal simplex variant for pure processing networks

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ACM Transactions on Mathematical Software (TOMS) archive
Volume 15 , Issue 1 (March 1989) table of contents

Pages: 64 - 78

Year of Publication: 1989

ISSN:0098-3500

Authors

Michael D. Chang	Gonzaga Univ., Spokane, WA
Chou-Hong J. Chen	Gonzaga Univ., Spokane, WA
Michael Engquist	Cleveland Consulting Associates, Austin, TX

Publisher

ACM New York, NY, USA

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Downloads (6 Weeks): 2, Downloads (12 Months): 27, Citation Count: 0

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ABSTRACT

In processing networks, ordinary network constraints are supplemented by proportional flow restrictions on arcs entering or leaving some nodes. This paper describes a new primal partitioning algorithm for solving pure processing networks using a working basis of variable dimension. In testing against MPSX/370 on a class of randomly generated problems, a FORTRAN implementation of this algorithm was found to be an order-of-magnitude faster. Besides indicating the use of our methods in stand-alone fashion, the computational results also demonstrate the desirability of using these methods as a high-level module in a mathematical programming system.

REFERENCES

Note: OCR errors may be found in this Reference List extracted from the full text article. ACM has opted to expose the complete List rather than only correct and linked references.

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INDEX TERMS

Primary Classification:
G. Mathematics of Computing
G.1 NUMERICAL ANALYSIS
G.1.6 Optimization
Subjects: Linear programming

Additional Classification:
G. Mathematics of Computing
G.2 DISCRETE MATHEMATICS
G.2.2 Graph Theory
Subjects: Network problems
G.4 MATHEMATICAL SOFTWARE
Subjects: Efficiency

General Terms:
Algorithms, Design, Performance, Theory

REVIEW

"Sven-Ake Gustafson : Reviewer"

Pure processing networks are minimum-cost flow problems in which proportional flow restrictions are permitted on arcs entering or leaving a node. The authors present an improved simplex algorithm for solving this class of problems. They report m more...

Collaborative Colleagues:

Michael D. Chang: colleagues

Chou-Hong J. Chen: colleagues

Michael Engquist: colleagues

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