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

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  • Marjan Akker

    (Utrecht University)

  • Han Hoogeveen

    (Utrecht University)

  • Judith Stoef

    (Utrecht University)

Abstract

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 $$\mathcal{NP}$$ NP -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.

Suggested Citation

  • Marjan Akker & Han Hoogeveen & Judith Stoef, 2018. "Combining two-stage stochastic programming and recoverable robustness to minimize the number of late jobs in the case of uncertain processing times," Journal of Scheduling, Springer, vol. 21(6), pages 607-617, December.
    • Handle: RePEc:spr:jsched:v:21:y:2018:i:6:d:10.1007_s10951-018-0559-z
    DOI: 10.1007/s10951-018-0559-z
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    References listed on IDEAS

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    Cited by:

    1. Gaia Nicosia & Andrea Pacifici & Ulrich Pferschy & Julia Resch & Giovanni Righini, 2021. "Optimally rescheduling jobs with a Last-In-First-Out buffer," Journal of Scheduling, Springer, vol. 24(6), pages 663-680, December.
    2. Shoufeng Ma & Hongming Li & Ning Zhu & Chenyi Fu, 2021. "Stochastic programming approach for unidirectional quay crane scheduling problem with uncertainty," Journal of Scheduling, Springer, vol. 24(2), pages 137-174, April.
    3. François Clautiaux & Boris Detienne & Henri Lefebvre, 2023. "A two-stage robust approach for minimizing the weighted number of tardy jobs with objective uncertainty," Journal of Scheduling, Springer, vol. 26(2), pages 169-191, April.
    4. Pei, Zhi & Lu, Haimin & Jin, Qingwei & Zhang, Lianmin, 2022. "Target-based distributionally robust optimization for single machine scheduling," European Journal of Operational Research, Elsevier, vol. 299(2), pages 420-431.
    5. Ulrich Pferschy & Julia Resch & Giovanni Righini, 2023. "Algorithms for rescheduling jobs with a LIFO buffer to minimize the weighted number of late jobs," Journal of Scheduling, Springer, vol. 26(3), pages 267-287, June.

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