Network flows: theory, algorithms, and applications
Network flows: theory, algorithms, and applications
Efficient algorithms for generalized cut trees
SODA '90 Proceedings of the first annual ACM-SIAM symposium on Discrete algorithms
On the Complexity of Scheduling Incompatible Jobs with Unit-Times
MFCS '93 Proceedings of the 18th International Symposium on Mathematical Foundations of Computer Science
The maximum flow problem with disjunctive constraints
Journal of Combinatorial Optimization
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We study the maximum flow problem subject to binary disjunctive constraints in a directed graph: A negative disjunctive constraint states that a certain pair of arcs in a digraph cannot be simultaneously used for sending flow in a feasible solution. In contrast to this, positive disjunctive constraints force that for certain pairs of arcs at least one arc has to carry flow in a feasible solution. Negative (positive) disjunctive constraints can be represented by a conflict (forcing) graph whose vertices correspond to the arcs of the underlying graph, and whose edges encode the constraints. We show that the maximum flow problem is strongly NP-hard, even if the conflict graph contains only isolated edges and the network consists only of disjoint paths. For forcing graphs the problem can be solved efficiently if fractional flow values are allowed. If flow values are required to be integral we provide the sharp line between polynomially solvable and strongly NP-hard instances.