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EPSRC Reference: EP/M003191/2
Title: Distributionally Robust Optimisation With Matrix Moment Constraints: A Semi-Infinite and Semi-Definite Programming Approach
Principal Investigator: Xu, Professor H
Other Investigators:
Researcher Co-Investigators:
Project Partners:
Department: School of Mathematics
Organisation: University of Southampton
Scheme: Standard Research
Starts: 01 April 2015 Ends: 31 August 2017 Value (£): 200,238
EPSRC Research Topic Classifications:
Mathematical Aspects of OR
EPSRC Industrial Sector Classifications:
No relevance to Underpinning Sectors
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Panel History:  
Summary on Grant Application Form
One of the most challenging issues in decision analysis is to find an optimal decision under uncertainty. The solvability of such a decision problem and the quality of the optimal decision rely heavily on available information on the underlying uncertainties which are often mathematically represented by a vector of random variables or a random process. If a decision maker has complete information on the distribution of the random parameters, then he can either obtain a closed form of the integral of the random functions in the problem and then convert it into a deterministic optimisation problem, or alternatively use various statistical and numerical integration approaches such as scenario method, Monte Carlo sampling method and quadrature rules to develop some approximation schemes and then solve this using standard linear/nonlinear programming codes.

The situation can become far more complex if the decision maker does not have complete information on the distribution of the random variables. For instance, if the decision maker does not have any information other than the range of the random variables, then it might be a reasonable strategy to choose an optimal decision on the basis of the worst scenario of the random parameters in order to immunize the risks from the uncertainty. This kind of decision making framework is known as robust optimisation and it is well known in engineering design where an optimal design must take into account of the extreme (albeit rare) event. However, this kind of robust scheme is not necessarily economical in that it sets out excessive resources for preventing a rare event. From numerical perspective, the resulting optimization problem could be intractable. A alternative and possibly less conservative robust optimisation model, which is known as distributionally robust optimisation, is to consider a set of distributions with historical data, computer simulation or subjective judgements which contain the true distribution with certain confidence and the optimal decision is chosen on the basis of the worst distribution rather than the worst scenario.

In this project, we concentrate on a class of distributionally robust optimization problems where the set of distributions is estimated through moment of random matrices which capture some partial information such as the mean value, the standard deviation or the correlation of the random variables.Through some duality theory in convex analysis, we transform the distributional robust optimization into mathematical programs with semi-infinite and semi-definite constraints (MPSISDC). Two fundamental questions arise: 1. If the moments are calculated from samples, how reliable are the optimal value and the optimal solution (or stationary points if the problem is nonconvex) obtained from solving the MPSISDC? This requires one to carry out comprehensive qualitative and quantitative statistical analysis. This kind of analysis is known as asymptotic convergence analysis or stability analysis in stochastic programming but little has been done for robust or distributionally robust optimization. 2. How do we solve the MPSISDC? This is a deterministic optimization problem which involves semi-definite and semi-infinite constraints with matrix variables. If the underlying function is linear or quadratic and the support of the random variables are polynomial or semi-algebraic, then the MPSISDC may be recast as a semi-definite programming problem or a convex conic programming problem, but here we do not assume the specific structure and hence there is no existing optimization method which can be readily applied to solve MPSISDC.

This project is to use MPSISDC as a platform to establish the theory of asymptotic analysis for the class of distributionally robust optimization problems and develop novel numerical methods for solving them.



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