Help
Cart
Skip main navigation

Available Issues

April 10, 2013 - June 5, 2026

Available Issues

April 10, 2013 - June 5, 2026

Model Aggregation for Risk Evaluation and Robust Optimization

Published Online:7 Nov 2025https://doi.org/10.1287/mnsc.2023.03523

References

  • Ararat Ç, Hamel AH, Rudloff B (2017) Set-valued shortfall and divergence risk measures. Internat. J. Theoret. Appl. Finance 20(5):1750026.CrossrefGoogle Scholar
  • Artzner P, Delbaen F, Eber JM, Heath D (1999) Coherent measures of risk. Math. Finance 9(3):203–228.CrossrefGoogle Scholar
  • Basel Committee on Banking Supervision (2019) Minimum Capital Requirements for Market Risk (Bank for International Settlements, Basel, Switzerland).Google Scholar
  • Bellini F, Klar B, Müller A, Rosazza Gianin E (2014) Generalized quantiles as risk measures. Insurance Math. Econom. 54(1):41–48.CrossrefGoogle Scholar
  • Ben-Tal A, Nemirovski A (2001) Lectures on Modern Convex Optimization: Analysis, Algorithms, and Engineering Applications (SIAM, Philadelphia).CrossrefGoogle Scholar
  • Blanchet J, Murthy K (2019) Quantifying distributional model risk via optimal transport. Math. Oper. Res. 44(2):565–600.LinkGoogle Scholar
  • Blanchet J, Chen L, Zhou X (2022) Distributionally robust mean-variance portfolio selection with Wasserstein distances. Management Sci. 68(9):6382–6410.LinkGoogle Scholar
  • Blanchet J, Kang Y, Murthy K (2019) Robust Wasserstein profile inference and applications to machine learning. J. Appl. Probab. 56(3):830–857.CrossrefGoogle Scholar
  • Cambou M, Filipović D (2017) Model uncertainty and scenario aggregation. Math. Finance 27(2):534–567.CrossrefGoogle Scholar
  • Cerreia-Vioglio S, Hansen LP, Maccheroni F, Marinacci M (2025) Making decisions under model misspecification. Rev. Econom. Stud. Forthcoming.CrossrefGoogle Scholar
  • Chambers CP (2009) An axiomatization of quantiles on the domain of distribution functions. Math. Finance 19(2):335–342.CrossrefGoogle Scholar
  • Chen L, He S, Zhang S (2011) Tight bounds for some risk measures, with applications to robust portfolio selection. Oper. Res. 59(4):847–865.LinkGoogle Scholar
  • Cherny AS, Madan D (2009) New measures for performance evaluation. Rev. Financial Stud. 22(7):2571–2606.CrossrefGoogle Scholar
  • Cont R, Deguest R, Scandolo G (2010) Robustness and sensitivity analysis of risk measurement procedures. Quant. Finance 10(6):593–606.CrossrefGoogle Scholar
  • Delage E, Ye Y (2010) Distributionally robust optimization under moment uncertainty with application to data-driven problems. Oper. Res. 58(3):595–612.LinkGoogle Scholar
  • Delage E, Kuhn D, Wiesemann W (2019) “Dice”-sion-making under uncertainty: When can a random decision reduce risk? Management Sci. 65(7):3282–3301.LinkGoogle Scholar
  • Dentcheva D (2023) Relations between risk-averse models in extended two-stage stochastic optimization. Serdica Math. J. 49(1–3):49–76.Google Scholar
  • Dentcheva D, Ruszczyński A (2003) Optimization with stochastic dominance constraints. SIAM J. Optim. 14(2):548–566.CrossrefGoogle Scholar
  • Dentcheva D, Ruszczyński A (2004) Optimality and duality theory for stochastic optimization problems with nonlinear dominance constraints. Math. Programming 99(2):329–350.CrossrefGoogle Scholar
  • El Ghaoui LME, Oks M, Oustry F (2003) Worst-case value-at-risk and robust portfolio optimization. Oper. Res. 51(4):543–556.LinkGoogle Scholar
  • Embrechts P, Puccetti G (2006) Bounds for functions of multivariate risks. J. Multivariate Anal. 97(2):526–547.CrossrefGoogle Scholar
  • Embrechts P, Puccetti G, Rüschendorf L (2013) Model uncertainty and VaR aggregation. J. Banking Finance 37(8):2750–2764.CrossrefGoogle Scholar
  • Embrechts P, Schied A, Wang R (2022) Robustness in the optimization of risk measures. Oper. Res. 70(1):95–110.LinkGoogle Scholar
  • Embrechts P, Mao T, Wang Q, Wang R (2021) Bayes risk, elicitability, and the expected shortfall. Math. Finance 31(4):1190–1217.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
  • Föllmer H, Schied A (2016) Stochastic Finance. An Introduction in Discrete Time, 4th ed. (Walter de Gruyter, Berlin).CrossrefGoogle Scholar
  • Gao R, Kleywegt AJ (2022) Distributionally robust stochastic optimization with Wasserstein distance. Math. Oper. Res. 48(2):603–655.LinkGoogle Scholar
  • Glasserman P, Xu X (2014) Robust risk measurement and model risk. Quant. Finance 14(1):29–58.CrossrefGoogle Scholar
  • Hamel AH, Heyde F (2010) Duality for set-valued measures of risk. SIAM J. Financial Math. 1(1):66–95.CrossrefGoogle Scholar
  • Hamel AH, Heyde F, Rudloff B (2011) Set-valued risk measures for conical market models. Math. Financial Econom. 5(1):1–28.CrossrefGoogle Scholar
  • Han X, Wang B, Wang R, Wu Q (2024) Risk concentration and the mean-expected shortfall criterion. Math. Finance 34(3):819–846.CrossrefGoogle Scholar
  • Hansen LP, Sargent TJ (2001) Robust control and model uncertainty. Amer. Econom. Rev. 91(2):60–66.CrossrefGoogle Scholar
  • He X, Peng X (2018) Surplus-invariant, law-invariant, and conic acceptance sets must be the sets induced by value-at-risk. Oper. Res. 66(5):1268–1276.LinkGoogle Scholar
  • Huang RJ, Tzeng LY, Zhao L (2020) Fractional degree stochastic dominance. Management Sci. 66(10):4630–4647.LinkGoogle Scholar
  • Jagannathan R (1977) Minimax procedure for a class of linear programs under uncertainty. Oper. Res. 25(1):173–177.LinkGoogle Scholar
  • Kertz RP, Rösler U (2000) Complete lattices of probability measures with applications to martingale theory. IMS Lecture Notes Monograph Ser. 35:153–177.Google Scholar
  • Klibanoff P, Marinacci M, Mukerji S (2005) A smooth model of decision making under uncertainty. Econometrica 73(6):1849–1892.CrossrefGoogle Scholar
  • Kou S, Peng X (2016) On the measurement of economic tail risk. Oper. Res. 64(5):1056–1072.LinkGoogle Scholar
  • Kupper M, Zapata JM (2021) Large deviations built on max-stability. Bernoulli 27(2):1001–1027.CrossrefGoogle Scholar
  • Kusuoka S (2001) On law invariant coherent risk measures. Advances in Mathematical Economics, vol. 3 (Springer, Tokyo), 83–95. Google Scholar
  • Leitner J (2005) A short note on second-order stochastic dominance preserving coherent risk measures. Math. Finance 15(4):649–651.CrossrefGoogle Scholar
  • Li YMJ (2018) Closed-form solutions for worst-case law invariant risk measures with application to robust portfolio optimization. Oper. Res. 66(6):1533–1541.LinkGoogle Scholar
  • Li L, Shao H, Wang R, Yang J (2018) Worst-case range value-at-risk with partial information. SIAM J. Financial Math. 9(1):190–218.CrossrefGoogle Scholar
  • Liu F, Wang R (2021) A theory for measures of tail risk. Math. Oper. Res. 46(3):1109–1128.LinkGoogle Scholar
  • Liu F, Mao T, Wang R, Wei L (2022) Inf-convolution, optimal allocations, and model uncertainty for tail risk measures. Math. Oper. Res. 47(3):2494–2519.LinkGoogle Scholar
  • Lo A (1987) Semiparametric upper bounds for option prices and expected payoffs. J. Financial Econom. 19(2):373–388.CrossrefGoogle Scholar
  • Maccheroni F, Marinacci M, Rustichini A (2006) Ambiguity aversion, robustness, and the variational representation of preferences. Econometrica 74(6):1447–1498.CrossrefGoogle Scholar
  • Markowitz H (1952) Portfolio selection. J. Finance 7(1):77–91.Google Scholar
  • McNeil AJ, Frey R, Embrechts P (2015) Quantitative Risk Management: Concepts, Techniques and Tools, rev. ed. (Princeton University Press, Princeton, NJ).Google Scholar
  • Müller A, Scarsini M (2006) Stochastic order relations and lattices of probability measures. SIAM J. Optim. 16(4):1024–1043.CrossrefGoogle Scholar
  • Müller A, Stoyan D (2002) Comparison Methods for Stochastic Models and Risks (John Wiley & Sons, Hoboken, NJ).Google Scholar
  • Müller A, Scarsini M, Tsetlin I, Winkler RL (2017) Between first and second-order stochastic dominance. Management Sci. 63(9):2933–2947.LinkGoogle Scholar
  • Natarajan K, Pachamanova D, Sim M (2008) Incorporating asymmetric distributional information in robust value-at-risk optimization. Management Sci. 54(3):573–585.LinkGoogle Scholar
  • Natarajan K, Sim M, Uichanco J (2010) Tractable robust expected utility and risk models for portfolio optimization. Math. Finance 20(4):695–731.CrossrefGoogle Scholar
  • Newey WK, Powell JL (1987) Asymmetric least squares estimation and testing. Econometrica 55(4):819–847.CrossrefGoogle Scholar
  • Olivares-Nadal AV, DeMiguel V (2018) A robust perspective on transaction costs in portfolio optimization. Oper. Res. 66(3):733–739.LinkGoogle Scholar
  • Pflug GC (2000) Some remarks on the value-at-risk and the conditional value-at-risk. Probabilistic Constrained Optimization: Methodology and Applications (Springer US, Boston), 272–281.CrossrefGoogle Scholar
  • Popescu I (2007) Robust mean-covariance solutions for stochastic optimization. Oper. Res. 55(1):98–112.LinkGoogle Scholar
  • Postek K, den Hertog D, Melenberg B (2016) Computationally tractable counterparts of distributionally robust constraints on risk measures. SIAM Rev. 58(4):603–650.CrossrefGoogle Scholar
  • Rockafellar RT, Uryasev S (2002) Conditional value-at-risk for general loss distributions. J. Banking Finance 26(7):1443–1471.CrossrefGoogle Scholar
  • Rothschild M, Stiglitz J (1970) Increasing risk I. A definition. J. Econom. Theory 2(3):225–243.CrossrefGoogle Scholar
  • Ruszczyński A, Shapiro A (2006) Optimization of convex risk functions. Math. Oper. Res. 31(3):433–452.LinkGoogle Scholar
  • Schmeidler D (1989) Subjective probability and expected utility without additivity. Econometrica 57(3):571–587.CrossrefGoogle Scholar
  • Shaked M, Shanthikumar JG (2007) Stochastic Orders, Springer Series in Statistics (Springer, New York).CrossrefGoogle Scholar
  • Shapiro A (2013) On Kusuoka representation of law invariant risk measures. Math. Oper. Res. 38(1):142–152.LinkGoogle Scholar
  • Shapiro A, Dentcheva D, Ruszczynski A (2021) Lectures on Stochastic Programming: Modeling and Theory (Society for Industrial and Applied Mathematics, Philadelphia).Google Scholar
  • Wang S (1995) Insurance pricing and increased limits ratemaking by proportional hazards transforms. Insurance Math. Econom. 17(1):43–54.CrossrefGoogle Scholar
  • Wang R, Ziegel JF (2021) Scenario-based risk evaluation. Finance Stochastics 25(4):725–756.CrossrefGoogle Scholar
  • Wang R, Zitikis R (2021) An axiomatic foundation for the expected shortfall. Management Sci. 67(3):1413–1429.LinkGoogle Scholar
  • Wang R, Peng L, Yang J (2013) Bounds for the sum of dependent risks and worst value-at-risk with monotone marginal densities. Finance Stochastics 17(2):395–417.CrossrefGoogle Scholar
  • Wang R, Wei Y, Willmot GE (2020) Characterization, robustness and aggregation of signed Choquet integrals. Math. Oper. Res. 45(3):993–1015.LinkGoogle Scholar
  • Wiesemann W, Kuhn D, Sim M (2014) Distributionally robust convex optimization. Oper. Res. 62(6):1203–1466.LinkGoogle Scholar
  • Wozabal D (2014) Robustifying convex risk measures for linear portfolios: A nonparametric approach. Oper. Res. 62(6):1302–1315.LinkGoogle Scholar
  • Yaari ME (1987) The dual theory of choice under risk. Econometrica 55(1):95–115.CrossrefGoogle Scholar
  • Zhu MS, Fukushima M (2009) Worst-case conditional value-at-risk with application to robust portfolio management. Oper. Res. 57(5):1155–1168.LinkGoogle 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