The Recoverable Robust Two-Level Network Design Problem

Álvarez-Miranda, Eduardo; Ljubić, Ivana; Raghavan, S.; Toth, Paolo

doi:10.1287/ijoc.2014.0606

Cited by 14 publications

(7 citation statements)

References 38 publications

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“…In the first stage, one can buy edges at a cheaper price, and when the sink gets revealed, one can buy the additionally needed edges at a higher price. This problem is closely related to the recoverable robust Two-level Network Design problem studied by Álvarez-Miranda et al (2015b). Given a graph with a root node r one must decide which edges to prepare, and whether this should be done by installing primary or secondary technology.…”

Section: Literaturementioning

confidence: 99%

Combining two-stage stochastic programming and recoverable robustness to minimize the number of late jobs in the case of uncertain processing times

Akker

Hoogeveen

Stoef

2018

J Sched

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Minimizing the number of late jobs on a single machine is a classic scheduling problem, which can be used to model the situation that from a set of potential customers, we have to select as many as possible whom we want to serve, while selling no to the other ones. This problem can be solved by Moore-Hodgson's algorithm, provided that all data are deterministic. We consider a stochastic variant of this problem, where we assume that there is a small probability that the processing times differ from their standard values as a result of some kind of disturbance. When such a disturbance occurs, then we must apply some recovery action to make the solution feasible again. This leads us to the area of recoverable robustness, which handles this uncertainty by modeling each possible disturbance as a scenario; in each scenario, the initial solution must then be made feasible by applying a given, simple recovery algorithm to it. Since we cannot accept previously rejected customers, our only option is to reject customers that would have been served in the undisturbed case. Our problem therefore becomes to find a solution for the undisturbed case together with a feasible recovery to every possible disturbance. Our goal hereby is to maximize the expected number of served customers; we assume here that we know the probability that a given scenario occurs. In this respect, our problem falls outside the area of the 'standard' recoverable robustness, which contains the worst-case recovery cost as a component of the objective. Therefore, we consider our approach as a combination of two-stage stochastic programming and recoverable robustness. We show that this problem is N P-hard in the ordinary sense even if there is only one scenario, and we present some sufficient conditions that allow us to find a part of the optimal solution in polynomial time. We further evaluate several solution methods to find an optimal solution, among which are dynamic programming, branch-and-bound, and branch-and-price.

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Section: Literaturementioning

confidence: 99%

Combining two-stage stochastic programming and recoverable robustness to minimize the number of late jobs in the case of uncertain processing times

Akker

Hoogeveen

Stoef

2018

J Sched

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“…Formulations and algorithms for different variants of the recoverable robust shortest path problem are given in [13]. Models, properties and exact algorithms for recoverable robust two-level network design problems are presented in [5]. A more general framework of the RRO is studied in [17] where multiple recovery stages are allowed.…”

Section: The Recoverable Robust Uflmentioning

confidence: 99%

“…Nonetheless, this additional robustness is obtained at the expenses of (i) an increase of the difficulty of the problem, since a larger search space must be considered, and (ii) an increase of the total solution cost, OP T RR , because more facilities have to be opened and more allocations have to be established in the first stage or because a new worst-case scenario induces a higher robust recovery cost (i.e., ω increases). The first of these effects has been coined as the Effort for Robustness in [5] called the Price of Robustness in [10].…”

Section: Trans Instances: Solutions Robustness and Recoverabilitymentioning

confidence: 99%

The recoverable robust facility location problem

Álvarez-Miranda

Fernández

Ljubić

2015

Transportation Research Part B: Methodological

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This work deals with a facility location problem in which location and allocation (transportation) policy is defined in two stages such that a first-stage solution should be robust against the possible realizations (scenarios) of the input data that can only be revealed in a second stage. This solution should be robust enough so that it can be recovered promptly and at low cost in the second stage. In contrast to some related modeling approaches from the literature, this new recoverable robust model is more general in terms of the considered data uncertainty; it can address situations in which uncertainty may be present in any of the following four categories: provider-side uncertainty, receiver-side uncertainty, uncertainty in-between, and uncertainty with respect to the cost parameters.For this novel problem, a sophisticated branch-and-cut framework based on Benders decomposition is designed and complemented by several non-trivial enhancements, including scenario sorting, dual lifting, branching priorities, matheuristics and zero-half cuts. Two large sets of instances that incorporate spatial and demographic information of countries such as Germany and US (transportation) and Bangladesh and the Philippines (disaster management) are introduced. They are used to analyze in detail the characteristics of the proposed model and the obtained solutions as well as the effectiveness, behavior and limitations of the designed algorithm.

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“…To the best of our knowledge the two-level rectilinear Steiner tree problem has not been considered before despite its practical importance [14,15]. It is loosely related to the hierarchical network design problems [1,5,7] or multi-level facility location problems [3,4]. However, those problems are structurally different, typically considering problems in graphs, and do not apply to our case.…”

Section: Introductionmentioning

confidence: 99%

Two-level rectilinear Steiner trees

Held

Kämmerling

2017

Computational Geometry

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Given a set P of terminals in the plane and a partition of P into k subsets P 1 , . . . , P k , a two-level rectilinear Steiner tree consists of a rectilinear Steiner tree T i connecting the terminals in each set P i (i = 1, . . . , k) and a top-level tree T top connecting the trees T 1 , . . . , T k . The goal is to minimize the total length of all trees. This problem arises naturally in the design of low-power physical implementations of parity functions on a computer chip.For bounded k we present a polynomial time approximation scheme (PTAS) that is based on Arora's PTAS for rectilinear Steiner trees after lifting each partition into an extra dimension.For the general case we propose an algorithm that predetermines a connection point for each T i and T top (i = 1, . . . , k). Then, we apply any approximation algorithm for minimum rectilinear Steiner trees in the plane to compute each T i and T top independently.This gives us a 2.37-factor approximation with a running time of O(|P | log |P |) suitable for fast practical computations. The approximation factor reduces to 1.63 by applying Arora's approximation scheme in the plane.

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The Recoverable Robust Two-Level Network Design Problem

Cited by 14 publications

References 38 publications

Combining two-stage stochastic programming and recoverable robustness to minimize the number of late jobs in the case of uncertain processing times

Combining two-stage stochastic programming and recoverable robustness to minimize the number of late jobs in the case of uncertain processing times

The recoverable robust facility location problem

Two-level rectilinear Steiner trees

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