Sampling Scenario Set Partition Dual Bounds for Multistage Stochastic Programs

Bakir, Ilke; Boland, Natashia; Dandurand, Brian; Erera, Alan L.

doi:10.1287/ijoc.2018.0885

Cited by 10 publications

(3 citation statements)

References 58 publications

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“…There has also been a stream of research studying bounds and approximation for riskaverse multi-stage stochastic mixed-integer programming problems (Maggioni and Pflug 2019;Mahmutogulları et al 2018;Sandıkçı and Özaltın 2017;Bakir et al 2020;Maggioni et al 2014;Maggioni and Pflug 2016;Sandıkçı et al 2013). Our focus in this paper is different from those by providing cutting plane algorithms based on the scenario dominance concept to tackle the computational difficulty of solving risk-averse multi-stage stochastic programs.…”

Section: Literature Review and Paper Contributionsmentioning

confidence: 99%

Stage-t scenario dominance for risk-averse multi-stage stochastic mixed-integer programs

Büyüktahtakın

2021

Ann Oper Res

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This paper presents a new and general approach, named “Stage-t Scenario Dominance,” to solve the risk-averse multi-stage stochastic mixed-integer programs (M-SMIPs). Given a monotonic objective function, our method derives a partial ordering of scenarios by pairwise comparing the realization of uncertain parameters at each time stage under each scenario. Specifically, we derive bounds and implications from the “Stage-t Scenario Dominance” by using the partial ordering of scenarios and solving a subset of individual scenario sub-problems up to stage t. Using these inferences, we generate new cutting planes to tackle the computational difficulty of risk-averse M-SMIPs. We also derive results on the minimum number of scenario-dominance relations generated. We demonstrate the use of this methodology on a stochastic version of the mean-conditional value-at-risk (CVaR) dynamic knapsack problem. Our computational experiments address those instances that have uncertainty, which correspond to the objective, left-hand side, and right-hand side parameters. Computational results show that our “scenario dominance"-based method can reduce the solution time for mean-risk, stochastic, multi-stage, and multi-dimensional knapsack problems with both integer and continuous variables, whose structure is similar to the mean-risk M-SMIPs, with varying risk characteristics by one-to-two orders of magnitude for varying numbers of random variables in each stage. Computational results also demonstrate that strong dominance cuts perform well for those instances with ten random variables in each stage, and ninety random variables in total. The proposed scenario dominance framework is general and can be applied to a wide range of risk-averse and risk-neutral M-SMIP problems.

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Section: Literature Review and Paper Contributionsmentioning

confidence: 99%

Stage-t scenario dominance for risk-averse multi-stage stochastic mixed-integer programs

Büyüktahtakın

2021

Ann Oper Res

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“…Former research presents bounds and approximation methods for risk-averse multi-stage stochastic mixed-integer programming problems, see, e.g., Sandıkçı & Özaltın (2017) , Mahmutoğulları, Çavuş, & Aktürk (2018) , and Bakir, Boland, Dandurand, & Erera (2020) . Büyüktahtakın (2021) presents a new scenario sub-problem and defines stage-

scenario dominance concept for the first time.…”

Section: Introductionmentioning

confidence: 99%

COVID-19: Data-Driven optimal allocation of ventilator supply under uncertainty and risk

Yin

Büyüktahtakın

Patel

2023

European Journal of Operational Research

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“…Instead, a scenario may be assigned to one or more scenario bundles, depending upon its membership scores. Besides these works, scenario bundling is being vigorously studied in other contexts, such as the multistage stochastic programs (Bakir et al, 2020;Carpentier et al, 2013;Escudero et al, 2016;Zenarosa et al, 2014) and the chanceconstrained programs (Ahmed et al, 2017;Deng et al, 2017).…”

Section: Introductionmentioning

confidence: 99%

Soft clustering-based scenario bundling for a progressive hedging heuristic in stochastic service network design

Jiang

Bai

Wallace

et al. 2021

Computers & Operations Research

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We present a method for bundling scenarios in a progressive hedging heuristic (PHH) applied to stochastic service network design, where the uncertain demand is represented by a finite number of scenarios. Given the number of scenario bundles, we first calculate a vector of probabilities for every scenario, which measures the association strength of a scenario to each bundle center. This membership score calculation is based on existing soft clustering algorithms such as Fuzzy C-Means (FCM) and Gaussian Mixture Models (GMM). After obtaining the probabilistic membership scores, we propose a strategy to determine the scenario-to-bundle assignment. By contrast, almost all existing scenario bundling methods such as K-Means (KM) assume before the scenario-to-bundle assignment that a scenario belongs to exactly one bundle, which is equivalent to requiring that the membership scores are Boolean values. The probabilistic membership scores bring many advantages over Boolean ones, such as the flexibility to create various degrees of overlap between scenario bundles and the capability to accommodate scenario bundles with different covariance structures. We empirically study the impacts of different degrees of overlap and covariance structures on PHH performance by comparing PHH based on FCM/GMM with that based on KM and the cover method, which represents the state-of-the-art scenario bundling algorithm for stochastic network design. The solution quality is measured against the lower bound provided by CPLEX. The experimental results show that, GMM-based PHH yields the best performance among all methods considered, achieving nearly equivalent solution quality in a fraction of the run-time of the other methods.

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Sampling Scenario Set Partition Dual Bounds for Multistage Stochastic Programs

Cited by 10 publications

References 58 publications

Stage-t scenario dominance for risk-averse multi-stage stochastic mixed-integer programs

Stage-t scenario dominance for risk-averse multi-stage stochastic mixed-integer programs

COVID-19: Data-Driven optimal allocation of ventilator supply under uncertainty and risk

Soft clustering-based scenario bundling for a progressive hedging heuristic in stochastic service network design

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