Pooling Problems with Polynomial-Time Algorithms

• Published in: Journal of optimization theory and applications Vol. 170; no. 2; pp. 591 - 615
• Main Authors: Haugland, Dag, Hendrix, Eligius M. T.
• Format: Journal Article
• Language: English
• Published: New York Springer US 01.08.2016; Springer Nature B.V
• Subjects: Algorithms; Applications of Mathematics; Calculus of Variations and Optimal Control; Optimization; Complexity; Computation; Computer science; Diet; Engineering; Global optimization; Integer programming; Linear programming; Logistics; Mathematical analysis; Mathematical models; Mathematics; Mathematics and Statistics; Natural gas; Networks; Operations Research/Decision Theory; Optimization; Polyhedra; Polynomial-time algorithm; Polynomials; Polytopes; Pooling problem; Pools; Studies; Terminals; Theory of Computation; Pooling problem; 68Q25; Global optimization; 90C35; 90C39; Polynomial-time algorithm; 90C26; Complexity
• ISSN: 0022-3239; 1573-2878
• DOI: 10.1007/s10957-016-0890-5

The computational challenge offered by many traditional network flow models is modest, and large-scale instances can be solved fast. When the composition of the flow is part of the model, the required computation time may increase substantially. This is in particular true for the pooling problem, where the relative content of certain flow components is restricted. Flow entering the network at the source nodes has a given composition, whereas the composition in other nodes is determined by the composition of entering flows. At the network terminals, the flow composition is subject to restrictions referred to as quality constraints. The pooling problem is known to be strongly NP-hard, even if the network has only one pool, but is solvable in polynomial time if also the number of terminals or the number of quality parameters (flow components) is bounded. The problem is also NP-hard if there are only two sources and terminals and only one quality parameter. Two related questions have been left open in the literature so far. For the single-pool version, it has not been known whether the problem is solvable in polynomial time if the number of sources is bounded. For the version with a single quality parameter and two sources and terminals, the question whether a pseudo-polynomial algorithm exists has been open. This paper gives positive answers to both questions.