An implementation of exact knapsack separation

Vasilyev, Igor; Boccia, Maurizio; Hanafi, Saïd

doi:10.1007/s10898-015-0294-3

Cited by 10 publications

(6 citation statements)

References 32 publications

(82 reference statements)

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“…The idea behind inequalities (24) is reminiscent of up-lifting and down-lifting in cutting plane theory. For instance, in a binary integer problem, a given inequality can be strengthened by considering the linear relaxation solution at a certain node of a branchand-bound tree and taking into account the previously performed branches to 0 or 1 (see, e.g., Kaparis andLetchford 2008, andVasilyev et al 2016).…”

Section: Improvement Methods For the Cscp-rmentioning

confidence: 99%

A scalable exact algorithm for the vertex p-center problem

Contardo¹,

Iori²,

Kramer³

2019

Computers & Operations Research

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The capacitated p-center problem requires to select p facilities from a set of candidates to service a number of customers, subject to facility capacity constraints, with the aim of minimizing the maximum distance between a customer and its associated facility. The problem is well known in the field of facility location, because of the many applications that it can model. In this paper, we solve it by means of search algorithms that iteratively seek the optimal distance by solving tailored subproblems. We present different mathematical formulations for the subproblems and improve them by means of several valid inequalities, including an effective one based on a 0-1 disjunction and the solution of subset sum problems. We also develop an alternative search strategy that finds a balance between the traditional sequential search and binary search. This strategy limits the number of feasible subproblems to be solved and, at the same time, avoids large overestimates of the solution value, which are detrimental for the search. We evaluate the proposed techniques by means of extensive computational experiments on benchmark instances from the literature and new larger test sets. All instances from the literature with up to 402 vertices and integer distances are solved to proven optimality, including 13 open cases, and feasible solutions are found in 10 minutes for instances with up to 3038 vertices.

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Section: Improvement Methods For the Cscp-rmentioning

confidence: 99%

A scalable exact algorithm for the vertex p-center problem

Contardo¹,

Iori²,

Kramer³

2019

Computers & Operations Research

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“…In order to test the effectiveness of the exact separation algorithm for solving the unsplittable capacitated network design problem, we implement it in C++ linked with IBM ILOG CPLEX optimizer 12.7.1 [16] library. Following [31], to avoid changing the problem structure, the presolving features are turned off in our experiments. Moreover, the dual simplex method is used to reoptimize the linear programming problem (27) after adding cutting planes.…”

Section: Numerical Resultsmentioning

confidence: 99%

“…To begin with, we note that since the number of constraints in problem ( 12) may be exponential, from a computational perspective, it is impractical to solve problem (12) when all the constraints are expressed explicitly. For this reason, we follow [31] to solve problem ( 12) by decomposing into the following four steps.…”

Section: An Exact Separation Algorithmmentioning

confidence: 99%

“…Vasilyev et al [31] suggested to use the enumeration of the multiplier θ from 2 to 10 4 and checked the integrality within the tolerance 10 −5 . To further avoid too much computational efforts, here we use the approach described in [1].…”

Section: Numerical Errorsmentioning

confidence: 99%

“…It is worth noting that the considered exact separation for the unsplittable flow arc-set polyhedron can be seen as an extension of the exact separation for the 0-1 knapsack polytope; see [5,6,9,10,11,12,20,31] and the references therein. The difference is that the exact separation for the 0-1 knapsack polytope cannot handle non-binary integer variables, whereas the approach in this paper takes the non-binary integer variables into consideration such that it can be customized to solve the unsplittable capacitated network design problem.…”

Section: Introductionmentioning

confidence: 99%

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An exact separation algorithm for unsplittable flow capacitated network design arc-set polyhedron

Chen

Yang

et al. 2020

Preprint

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In this paper, we concentrate on generating cutting planes for the unsplittable capacitated network design problem. We use the unsplittable flow arc-set polyhedron of the considered problem as a substructure and generate cutting planes by solving the separation problem over it. To relieve the computational burden, we show that, in some special cases, a closed form of the separation problem can be derived. For the general case, a brute-force algorithm, called exact separation algorithm, is employed in solving the separation problem of the considered polyhedron such that the constructed inequality guarantees to be facet-defining. Furthermore, a new technique is presented to accelerate the exact separation algorithm, which significantly decreases the number of iterations in the algorithm. Finally, a comprehensive computational study on the unsplittable capacitated network design problem is presented to demonstrate the effectiveness of the proposed algorithm.

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Local Cuts for 0–1 Multidimensional Knapsack Problems

2017

Lecture Notes in Management and Industrial Engineering

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An implementation of exact knapsack separation

Cited by 10 publications

References 32 publications

A scalable exact algorithm for the vertex p-center problem

A scalable exact algorithm for the vertex p-center problem

An exact separation algorithm for unsplittable flow capacitated network design arc-set polyhedron

Local Cuts for 0–1 Multidimensional Knapsack Problems

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