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TIGHT BOUNDS ON EXPECTED ORDER STATISTICS

Published online by Cambridge University Press:  19 September 2006

Dimitris Bertsimas
Affiliation:
Sloan School of Management and Operations Research Center, Massachusetts Institute of Technology, Cambridge, MA 02139, E-mail: [email protected]
Karthik Natarajan
Affiliation:
Department of Mathematics, National University of Singapore, Singapore 117543, E-mail: [email protected]
Chung-Piaw Teo
Affiliation:
Department of Decision Sciences, NUS Business School, Singapore 117591, E-mail: [email protected]

Abstract

In this article, we study the problem of finding tight bounds on the expected value of the kth-order statistic E [Xk:n] under first and second moment information on n real-valued random variables. Given means E [Xi] = μi and variances Var[Xi] = σi2, we show that the tight upper bound on the expected value of the highest-order statistic E [Xn:n] can be computed with a bisection search algorithm. An extremal discrete distribution is identified that attains the bound, and two closed-form bounds are proposed. Under additional covariance information Cov[Xi,Xj] = Qij, we show that the tight upper bound on the expected value of the highest-order statistic can be computed with semidefinite optimization. We generalize these results to find bounds on the expected value of the kth-order statistic under mean and variance information. For k < n, this bound is shown to be tight under identical means and variances. All of our results are distribution-free with no explicit assumption of independence made. Particularly, using optimization methods, we develop tractable approaches to compute bounds on the expected value of order statistics.

Type
Research Article
Copyright
© 2006 Cambridge University Press

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References

REFERENCES

Andreasen, J. (1998). The pricing of discretely sampled Asian and lookback options: A change of numeraire approach. Journal of Computational Finance 2(1): 530.Google Scholar
Arnold, B.C. & Balakrishnan, N. (1989). Relations, bounds and approximations for order statistics. Lecture Notes in Statistics No. 53. Berlin: Springer-Verlag.
Arnold, B.C. & Groeneveld, R.A. (1979). Bounds on expectations of linear systematic statistics based on dependent samples. Mathematics of Operations Research 4(4): 441447.Google Scholar
Aven, T. (1985). Upper (lower) bounds on the mean of the maximum (minimum) of a number of random variables. Journal of Applied Probability 22: 723728.Google Scholar
Bertsimas, D., Natarajan, K., & Teo, C.-P. (2004). Probabilistic combinatorial optimization: Moments, semidefinite programming and asymptotic bounds. SIAM Journal of Optimization 15(1): 185209.Google Scholar
Bertsimas, D. & Popescu, I. (2002). On the relation between option and stock prices: A convex optimization approach. Operations Research 50(2): 358374.Google Scholar
Black, F. & Scholes, M. (1973). The pricing of options and corporate liabilities. Journal of Political Economy 81: 637654.Google Scholar
Boyle, P. & Lin, X.S. (1997). Bounds on contingent claims based on several assets. Journal of Financial Economics 46: 383400.Google Scholar
David, H.A. & Nagaraja, H.N. (2003). Order statistics, 3rd ed. New York: Wiley.
Gumbel, E.J. (1954). The maximum of the mean largest value and of the range. Annals of Mathematical Statistics 25: 7684.Google Scholar
Hartley, H.O. & David, H.A. (1954). Universal bounds for mean range and extreme observations. Annals of Mathematical Statistics 25: 8589.Google Scholar
Isii, K. (1963). On the sharpness of Chebyshev-type inequalities. Annals of the Institute of Statistical Mathematics 14: 185197.Google Scholar
Jagannathan, R. (1976). Minimax procedure for a class of linear programs under uncertainty. Operations Research 25(1): 173176.Google Scholar
Karlin, S. & Studden, W.J. (1966). Tchebycheff systems: With applications in analysis and statistics. New York: Wiley–Interscience.
Lai, T.L. & Robbins, H. (1976). Maximally dependent random variables. Proceedings of the National Academy of the Sciences of the United States of America 73(2): 286288.Google Scholar
Lo, A.W. (1987). Semi-parametric upper bounds for option prices and expected payoffs. Journal of Financial Economics 19: 373387.Google Scholar
Meilijson, I. & Nadas, A. (1979). Convex majorization with an application to the length of critical path. Journal of Applied Probability 16: 671677.Google Scholar
Moriguti, S. (1951). Extremal properties of extreme value distributions. Annals of Mathematical Statistics 22: 523536.Google Scholar
Nesterov, Y. & Nemirovkii, A. (1994). Interior point polynomial algorithms for convex programming. Studies in Applied Mathematics 13. Philadelphia: Society for Industrial and Applied Mathematics.
Parillo, P.A. (2000). Structured semidefinite programs and semi-algebraic geometry methods in robustness and optimization. PhD thesis, California Institute of Technology.
Ross, S.M. (2003). Introduction to probability models, 8th ed. New York: Academic Press.
Scarf, H. (1958). A min-max solution of an inventory problem. In K.J. Arrow, S. Karlin, & H. Scarf (eds.). Studies in the mathematical theory of inventory and production. Stanford, CA: Stanford University Press, pp. 201209.
Sturm, J.F. SeDuMi version 1.03. Available from http://sedumi.mcmaster.ca/.