Help
Cart
Skip main navigation

Available Issues

April 10, 2013 - June 5, 2026

Available Issues

April 10, 2013 - June 5, 2026

Data-Driven Reliable Facility Location Design

Published Online:4 Dec 2024https://doi.org/10.1287/mnsc.2021.02115

References

  • Aboolian R, Cui T, Shen ZJM (2013) An efficient approach for solving reliable facility location models. INFORMS J. Comput. 25(4):720–729.LinkGoogle Scholar
  • An Y, Zeng B, Zhang Y (2014) Reliable p-median facility location problem: Two-stage robust models and algorithms. Transportation Res. Part B Methodological 64:54–72.CrossrefGoogle Scholar
  • Banker S (2016) Using weather data to improve supply chain resiliency. Forbes (June 29), https://www.forbes.com/sites/stevebanker/2016/06/29/using-weather-to-improve-supply-chain-resiliency/#23a609a823f2.Google Scholar
  • Bayraksan G, Love DK (2015) Data-driven stochastic programming using phi-divergences. Aleman D, Thiele AC, eds. The Operations Research Revolution (INFORMS, Catonsville, MD), 1–19.LinkGoogle Scholar
  • Ben-Tal A, Den Hertog D, De Waegenaere A, Melenberg B, Rennen G (2013) Robust solutions of optimization problems affected by uncertain probabilities. Management Sci. 59(2):341–357.LinkGoogle Scholar
  • Berman O, Krass D, Menezes M (2007) Facility reliability issues in network p-median problems: Strategic centralization and co-location effects. Oper. Res. 55(2):332–350.LinkGoogle Scholar
  • Bertsimas D, Gupta V, Kallus N (2018a) Data-driven robust optimization. Math. Programming 167(2):235–292.CrossrefGoogle Scholar
  • Bertsimas D, Gupta V, Kallus N (2018b) Robust sample average approximation. Math. Programming 171(1):217–282.CrossrefGoogle Scholar
  • Bertsimas D, Shtern S, Sturt B (2022) A data-driven approach to multistage stochastic linear optimization. Management Sci. 69(1):51–74.LinkGoogle Scholar
  • Chen Q, Li X, Ouyang Y (2011) Joint inventory-location problem under the risk of probabilistic facility disruptions. Transportation Res. Part B Methodological 45(7):991–1003.CrossrefGoogle Scholar
  • Chen Z, Sim M, Xiong P (2020) Robust stochastic optimization made easy with RSOME. Management Sci. 66(8):3329–3339.LinkGoogle Scholar
  • Cheng C, Adulyasak Y, Rousseau LM (2021) Robust facility location under demand uncertainty and facility disruptions. Omega 103:102429.CrossrefGoogle Scholar
  • Cheng C, Qi M, Zhang Y, Rousseau LM (2018) A two-stage robust approach for the reliable logistics network design problem. Transportation Res. Part B Methodological 111:185–202.CrossrefGoogle Scholar
  • Church RL, Scaparra MP (2007) Protecting critical assets: The r-interdiction median problem with fortification. Geographical Anal. 39(2):129–146.CrossrefGoogle Scholar
  • Cui T, Ouyang Y, Shen ZJM (2010) Reliable facility location design under the risk of disruptions. Oper. Res. 58(4):998–1011.LinkGoogle Scholar
  • Erdoğan E, Iyengar G (2006) Ambiguous chance constrained problems and robust optimization. Math. Programming 107(1):37–61.CrossrefGoogle Scholar
  • Esfahani PM, Kuhn D (2018) Data-driven distributionally robust optimization using the Wasserstein metric: Performance guarantees and tractable reformulations. Math. Programming 171(1):115–166.CrossrefGoogle Scholar
  • Hao Z, He L, Hu Z, Jiang J (2020) Robust vehicle pre-allocation with uncertain covariates. Production Oper. Management 29(4):955–972.CrossrefGoogle Scholar
  • Hu Z, Hong LJ (2013) Kullback-Leibler divergence constrained distributionally robust optimization. Optim. Online 1(2):9.Google Scholar
  • Jiang R, Guan Y (2016) Data-driven chance constrained stochastic program. Math. Programming 158(1):291–327.CrossrefGoogle Scholar
  • Kapadia S (2021) Winter storm slams Texas food supply chains, logistics networks. Supply Chain Dive (February 19), https://www.supplychaindive.com/news/winter-storm-texas-food-grocery-heb-supply-chains-logistics/595354/.Google Scholar
  • Kleywegt AJ, Shapiro A, Homem-de Mello T (2002) The sample average approximation method for stochastic discrete optimization. SIAM J. Optim. 12(2):479–502.CrossrefGoogle Scholar
  • Ledbetter K (2021) Texas grocery stores emptied by winter storm. Texas A&M Today (February 23), https://today.tamu.edu/2021/02/23/texas-grocery-stores-emptied-by-winter-storm/.Google Scholar
  • Li X, Ouyang Y (2010) A continuum approximation approach to reliable facility location design under correlated probabilistic disruptions. Transportation Res. Part B Methodological 44(4):535–548.CrossrefGoogle Scholar
  • Li Y, Li X, Shu J, Song M, Zhang K (2022) A general model and efficient algorithms for reliable facility location problem under uncertain disruptions. INFORMS J. Comput. 34(1):407–426.LinkGoogle Scholar
  • Liberatore F, Scaparra MP, Daskin MS (2012) Hedging against disruptions with ripple effects in location analysis. Omega 40(1):21–30.CrossrefGoogle Scholar
  • Lim AE, Shanthikumar JG, Shen ZM (2006) Model uncertainty, robust optimization, and learning. Johnson MP, Norman B, Secomandi N, eds. Models, Methods, and Applications for Innovative Decision Making (INFORMS, Catonsville, MD), 66–94.LinkGoogle Scholar
  • Lim M, Daskin MS, Bassamboo A, Chopra S (2013) Facility location decisions with random disruptions and imperfect estimation. Manufacturing Service Oper. Management 15(2):239–249.LinkGoogle Scholar
  • Lu M, Ran L, Shen ZJM (2015) Reliable facility location design under uncertain correlated disruptions. Manufacturing Service Oper. Management 17(4):445–455.LinkGoogle Scholar
  • Luo F, Mehrotra S (2020) Distributionally robust optimization with decision dependent ambiguity sets. Optim. Lett. 14(8):2565–2594.CrossrefGoogle Scholar
  • Naaman M (2021) On the tight constant in the multivariate Dvoretzky–Kiefer–Wolfowitz inequality. Statist. Probab. Lett. 173:109088.CrossrefGoogle Scholar
  • Nemhauser GL, Wolsey LA (1981) Maximizing submodular set functions: Formulations and analysis of algorithms. Hansen P, ed. Annals of Discrete Mathematics (11): Studies on Graphs and Discrete Programming. North-Holland Mathematics Studies, vol. 59 (Elsevier, Amsterdam), 279–301.CrossrefGoogle Scholar
  • Pflug G, Wozabal D (2007) Ambiguity in portfolio selection. Quant. Finance 7(4):435–442.CrossrefGoogle Scholar
  • Qi L, Shen ZJM, Snyder LV (2009) A continuous-review inventory model with disruptions at both supplier and retailer. Production Oper. Management 18(5):516–532.CrossrefGoogle Scholar
  • Shen H, Liang Y, Shen ZJM (2021) Reliable hub location model for air transportation networks under random disruptions. Manufacturing Service Oper. Management 23(2):388–406.AbstractGoogle Scholar
  • Shen ZJM, Zhan RL, Zhang J (2011) The reliable facility location problem: Formulations, heuristics, and approximation algorithms. INFORMS J. Comput. 23(3):470–482.LinkGoogle Scholar
  • Shen H, Liang Y, Shen ZJM, Teo CP (2019) Reliable flexibility design of supply chains via extended probabilistic expanders. Production Oper. Management 28(3):700–720.CrossrefGoogle Scholar
  • Snyder LV, Daskin MS (2005) Reliability models for facility location: The expected failure cost case. Transportation Sci. 39(3):400–416.LinkGoogle Scholar
  • Snyder LV, Atan Z, Peng P, Rong Y, Schmitt AJ, Sinsoysal B (2016) OR/MS models for supply chain disruptions: A review. IIE Trans. 48(2):89–109.CrossrefGoogle Scholar
  • Speare-Cole R (2021) Texans face empty supermarket shelves as weather crisis hits supply chains. Newsweek (February 22), https://www.newsweek.com/texas-empty-supermarket-shelves-weather-crisis-supply-chains-1570971.Google Scholar
  • Van Parys BP, Esfahani PM, Kuhn D (2021) From data to decisions: Distributionally robust optimization is optimal. Management Sci. 67(6):3387–3402.LinkGoogle Scholar
  • Wozabal D (2012) A framework for optimization under ambiguity. Ann. Oper. Res. 193(1):21–47.CrossrefGoogle Scholar
  • Xie W (2020) Tractable reformulations of two-stage distributionally robust linear programs over the type-∞ Wasserstein ball. Oper. Res. Lett. 48(4):513–523.CrossrefGoogle Scholar
  • Xie S, An K, Ouyang Y (2019) Planning facility location under generally correlated facility disruptions: Use of supporting stations and quasi-probabilities. Transportation Res. Part B Methodological 122:115–139.CrossrefGoogle Scholar
  • Xie S, Li X, Ouyang Y (2015) Decomposition of general facility disruption correlations via augmentation of virtual supporting stations. Transportation Res. Part B Methodological 80:64–81.CrossrefGoogle Scholar
  • Yang Z, Aydin G, Babich V, Beil DR (2009) Supply disruptions, asymmetric information, and a backup production option. Management Sci. 55(2):192–209.LinkGoogle Scholar
  • Zhang Y, Snyder LV, Qi M, Miao L (2016) A heterogeneous reliable location model with risk pooling under supply disruptions. Transportation Res. Part B Methodological 83:151–178.CrossrefGoogle Scholar
Previous
Back to Top
Next
INFORMS site uses cookies to store information on your computer. Some are essential to make our site work; Others help us improve the user experience. By using this site, you consent to the placement of these cookies. Please read our Privacy Statement to learn more.
Agree