A Constraint Programming Approach for Solving a Queueing Design and Control Problem

Terekhov, Daria; Beck, J. Christopher; Brown, Kenneth N.

doi:10.1287/ijoc.1080.0307

Cited by 14 publications

(4 citation statements)

References 24 publications

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“…Though we can see logic-based Benders' cuts in any form, they must be formularized in the form of linear inequalities because the major problem is an MILP. This method has been used in various combinatorial optimization problems, such as logic circuits' verification by Hooker and Yan [36]; scheduling and planning by Hooker [36,37]; Benini [38]; Bajestani and Beck [39]; deterministic and stochastic location/fleet management by Fazel Zarandi and Beck [17]; Zarandi [31] and finally, control and queue design by Terekhov [40].…”

Section: Solving Methodology 41 Logic-based Benders' Decomposition (L...mentioning

confidence: 99%

A Bender’s Algorithm of Decomposition Used for the Parallel Machine Problem of Robotic Cell

et al. 2021

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The present research addresses the single transportation robot used to alleviate problems of robotic cell scheduling of the machines. For the purpose of minimizing the make-span, a model of mixed-integer linear programming (MILP) has been suggested. Since the inefficiency exists in NP-hard, a decomposition algorithm posed by Bender was utilized to alleviate the problem in real life situations. The proposed algorithm can be regarded as an efficient attempt to apply optimality Bender’s cuts regarding the problem of parallel machine robotic cell scheduling in order to reach precise resolutions for medium and big sized examples. The numerical analyses have demonstrated the efficiency of the proposed solving approach.

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Section: Solving Methodology 41 Logic-based Benders' Decomposition (L...mentioning

confidence: 99%

A Bender’s Algorithm of Decomposition Used for the Parallel Machine Problem of Robotic Cell

et al. 2021

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“…In the transportation logistics domain, they include food distribution [110], bicycle sharing [73,74], lock scheduling [123], and supply chain scheduling [115]. Other applications are project scheduling [70], robust call center scheduling [28], task scheduling for satellites [129], course timetabling [19], wind turbine maintenance scheduling [42], queuing design and control [113,114], service restoration planning for infrastructure networks [50], and sports scheduling [23,94,95,120,121].…”

Section: Other Scheduling and Logistics Problemsmentioning

confidence: 99%

Logic-Based Benders Decomposition for Large-Scale Optimization

Hooker

2019

Springer Optimization and Its Applications

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Logic-based Benders decomposition (LBBD) is a substantial generalization of classical Benders decomposition that, in principle, allows the subproblem to be any optimization problem rather than specifically a linear or nonlinear programming problem. It is amenable to a wide variety large-scale problems that decouple or otherwise simplify when certain decision variables are fixed. This chapter presents the basic theory of LBBD and explains how classical Benders decomposition is a special case. It also describes branch and check, a variant of LBBD that solves the master problem only once. It illustrates in detail how Benders cuts and subproblem relaxations can be developed for some planning and scheduling problems. It then describes the role of LBBD in three large-scale case studies. The chapter concludes with an extensive survey of the LBBD literature, organized by problem domain, to allow the reader to explore how Benders cuts have been developed for a wide range of applications.

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“…Logic-based Benders decomposition has been shown to be effective in a wide range of problems including scheduling (Hooker, 2005(Hooker, , 2007Beck, 2010), facility and vehicle allocation (Fazel-Zarandi & Beck, 2012), and queue design and control problems (Terekhov, Beck, & Brown, 2009).…”

Section: Logic-based Benders Decompositionmentioning

confidence: 99%

Scheduling a Dynamic Aircraft Repair Shop with Limited Repair Resources

Bajestani¹,

Beck²

2013

jair

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We address a dynamic repair shop scheduling problem in the context of military aircraft fleet management where the goal is to maintain a full complement of aircraft over the long-term. A number of flights, each with a requirement for a specific number and type of aircraft, are already scheduled over a long horizon. We need to assign aircraft to flights and schedule repair activities while considering the flights requirements, repair capacity, and aircraft failures. The number of aircraft awaiting repair dynamically changes over time due to failures and it is therefore necessary to rebuild the repair schedule online. To solve the problem, we view the dynamic repair shop as successive static repair scheduling sub-problems over shorter time periods. We propose a complete approach based on the logic-based Benders decomposition to solve the static sub-problems, and design different rescheduling policies to schedule the dynamic repair shop. Computational experiments demonstrate that the Benders model is able to find and prove optimal solutions on average four times faster than a mixed integer programming model. The rescheduling approach having both aspects of scheduling over a longer horizon and quickly adjusting the schedule increases aircraft available in the long term by 10% compared to the approaches having either one of the aspects alone

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A Constraint Programming Approach for Solving a Queueing Design and Control Problem

Cited by 14 publications

References 24 publications

A Bender’s Algorithm of Decomposition Used for the Parallel Machine Problem of Robotic Cell

A Bender’s Algorithm of Decomposition Used for the Parallel Machine Problem of Robotic Cell

Logic-Based Benders Decomposition for Large-Scale Optimization

Scheduling a Dynamic Aircraft Repair Shop with Limited Repair Resources

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