Stochastic Programming Mathematics and Its Applications Managing Editor: M. HAZEWINKEL Centre/or Mathematics and Computer Science, Amsterdam, The Netherlands Volume 324 Stochastic Programming by Andras Prekopa RUTCOR, Rutgers Center/or Operations Research, Rutgers University, New Brunswick, NJ, U.S.A. and Department o/Operations Research, £Orand Eiitviis University, Budapest, Hungary .. SPRINGER-SCIENCE+BUSINESS MEDIA, B.V. A C.I.P. Catalogue record for this book is available from the Library of Congress. ISBN 978-90-481-4552-2 ISBN 978-94-017-3087-7 (eBook) DOI 10.1007/978-94-017-3087-7 Ali Rights Reserved © 1995 Andrâs Prekopa Originally published by Kluwer Academic Publishers in 1995 No part of the material protected by this copyright notice may be reproduced or utilized in any form or by any means, electronic or mechanical, inc1uding photocopying, recording or by any information storage and retrieval system, without written permis sion from the copyright owner. To my wife Kinga Preface At the beginning of the nineteen fifties, when I was a young graduate student in probability theory and statistics at the Institute for Applied Mathematics of the Hungarian Academy of Sciences, I was required to work on theoretical and applied problems, just like the other members of the Institute. Applications which were based on advanced theory and/or gave rise to novel theoretical developments, were the most wanted and appreciated. However, our possibilities to satisfy the requirements imposed on us were strongly limited, because the country was in ruins due to World War II and the subsequent economic and political changes. Some of the engineering problems still looked hopeful and I began to deal with probabilistic and statistical type water resources problems. The chief water engineer of the city of Budapest was furious when I offered my applied mathematics for the benefit of the water supply of the city, because the main problem was to secure funds to build new wells at the banks of the Duna River to the north of Budapest. Another water engineer was more cooperative but his problem did not attract my interest. I found a reasonable probabilistic problem in determining the size of a water reservoir, intended to serve a new thermal power station, in the northern part of the country. I found an "ad hoc" solution to the problem: what is the smallest size of the reservoir still enough to deliver the necessary amount of water by a prescribed large probability? I could have been one of the inventors of the so-called "Moran dam model", because first I tried to solve the problem along that line, in a theoretically nice way. But my collegues and I rejected it because no river in Hungary had random water inputs which could be regarded as a sequence of Li.d. random variables, in the subsequent periods, let alone the fact that the water flow is a continuous rather than a discrete process. The lack of applicability of higher level mathematics to the given problem was disappointing. In the early months of nineteen fifty-seven I encountered linear programming and read more about operations research. I was fascinated by seeing that we were able to viii Preface find extrema of linear functions over completely arbitrary convex polyhedra. There were limitations regarding the number of inequalities and variables involved, due to computational difficulties, but there were none regarding the type of the convex polyhedra involved. That is what we need in probability and statistics, I told myself, to be able to solve problems under fairly general restrictions regarding the type of the random variables involved. There were other colleagues too who had the same in mind. Already in the nineteen fifties mathematical programming underwent a rapid de velopment, and answers have been proposed for the question: what to do with a linear or nonlinear programming problem when some of its parameters are random variables. Stochastic programming came to existence. Models and methods have been created which offered some solutions to the above-mentioned problems too. However, many years had to pass until stochastic programming became sufficiently well-developed to satisfy the above-mentioned expectations. How can we define this science? Two defini tions are presented below. First definition: stochastic programming is the science which offers solutions for problems formulated in connection with stochastic systems, where the resulting nu merical problem to be solved is a mathematical programming problem of nontrivial size. Second definition: stochastic programming handles mathematical programming problems, where some of the parameters are random variables; either we study the statistical properties of the random optimum value or other random variables that come up with the problem, or we reformulate it into a decision type problem by taking into account the joint probability distribution of the random parameters. The resulting problems in both definitions are called stochastic programming problems. The mathematical programming problems which serve as starting prob lems, mentioned in the second definition, are called base problems or underlying problems. We suggest that both definitions should be accepted. Disregarding the distribu tion problem$, which are only covered by the second definition, all other stochastic programming problems are covered by the first definition. In view of the first definition, moment problems and probability approximation schemes are parts of stochastic programming problems as long as mathematical pro gramming methods are used in them. At the same time these provide us with exam ples, where there are no underlying deterministic problems because the moments of a constant random variable are uninteresting and in this case the moment problems become trivial. Stochastic programming decision models can be subdivided into static and dy namic models, and both types may use probabilistic constraints and/or penalties in the objective function. A probabilistic constraint prescribes by a large probability that some constraints which are random while the decision is made, should hold by the time when the random variables in them are realized. Penalties added to the system costs in the objective function express costs incurred by the violations of the constraints when the random variables are realized. Preface ix The use of probabilistic constraint versus penalties is frequently debated. Critics say about models where only probabilistic constraints are used that: (a) the prob ability level in the probabilistic constraint is arbitrarily chosen, hence the problem is not well defined; (b) since we usually prescribe that some relations should hold by large probability, the tail of a probability distribution plays an important role in the decision making; however, the tail probabilities are frequently hard to estimate with satisfactory precision; (c) only the system costs are taken into account and the costs incurred by the uncertainty are left out of consideration. Models using only penalties in the objective function, without probabilistic con straint, can also be criticized: (0) the penalty is an expectation of some random variable which measures how m'llch the constraints are unsatisfied; the expectation is a long term average, hence the model is realistic only if the system operates for a long period of time (note that if a probabilistic constraint is used with a large probability level, then the event that has at least the prescribed probability can be regarded a practically sure event; thus, the event on which the probabilistic constraint is im posed is practically sure and even if we operate the system in a single period, our decision principle provides us with a reasonable result); ((3) the cost of violation of some constraints in the underlying problem is frequently unknown; (,) no reliability requirement is imposed on the system, hence it may fail (e.g., an insurance compa ny may go bankrupt) incurring such large costs which are not represented by the penalties. The above criticisms are sometimes justified but not always. The following points can be made: (a) there are cases in which the optimum values and the optimal solutions are not significantly sensitive for the choice of a large enough probability level in the probabilistic constraint; on the other hand, sometimes we can tell how rarely we may allow some of the stochastic constraints to be violated so that the system should survive; (b) sometimes the tail probabilities can be well approximated, e.g., by the use of moments which in turn, can frequently be well estimated; (c) the cost of uncertainty may be unknown; (0) sometimes we can operate the system for a long period of time; ((3) there are cases where the penalties of constraint violations are known; (,) there are cases where system reliability can be left out of consideration because if a constraint is violated, then we can use a compensation for cost. The above reasoning shows that the best model construction is the one which combines the use of a probabilistic constraint and penalties in the objective function. In practice, however, some other aspect, for example the numerical solvability of the problem also comes into account, and there is a tradeoff between correct statistical modelling and computability. The arsenal of practical problems where stochastic programming can be used is very large and it is difficult to place one model construction over another as more important. The book is a graduate textbook. The field is very large, hence a selection ofthe topics was unavoidable. An introduction to linear programming is presented in the first three chapters. My intention was to make it easily accessible for probabilists and statisticians and attract their interest to work on stochastic programming. The field needs them very x Preface much. In addition to linear programming, there are other prerequisites to read this book: nonlinear programming, probability theory, and statistics. Due to limitations regarding the size of the book I declined to include further introductory chapters. Chapter 4 is devoted to logconcave probability measures and their extensions. Multivariate logconcave measures first arose in stochastic programming more than twenty years ago, and became widely used and investigated in other fields such as probability theory, statistics, geometry, and mathematical analysis. Logconcave mea sures and their extensions provide us with the mathematical tools to establish the convexity of some of the stochastic programming problems, especially probabilistic constrained problems. Therefore, an in-depth presentation of the relevant most im portant theorems is appropriate. Chapter 5 presents fundamentals of optimization type moment problems which are stochastic programming problems in their own right and are used in other stochastic programming model constructions. A large part of this chapter is devoted to discrete moment problems which came to prominence concerning bounding probabilities of Boolean functions of events and sets in higher dimensional spaces. Chapter 6 pays more attention to these bounding procedures and presents prob ability approximation schemes, combining numerical integration and simulation. Chapter 7 presents statistical decision theoretical principles in a historical frame work. It explains where the model constructions of stochastic programming come from. Chapter 8 summarizes the basic static type stochastic programming model con structions. Chapter 9 presents in detail two solution techniques for the simple recourse prob lem for the case of discrete random variables. They use the so-called 0- and A representations of a piecewise linear function. It is also shown how the case of the continuously distributed random variables can be treated. Chapter 10 deals with the theorems concerning the convexity of probabilistic constrained stochastic programming problems. Many of them are derived from the results of Chapter 4. Chapter 11 is devoted to programming under probabilistic constraints and the methodologically similar problem: maximizing a probability under constraints. More work has been done for the case of continuous random variables but at the end of the chapter a few results are mentioned for the case of the discrete distribution. In this chapter some nonlinear programming algorithms are presented which have been tested for the solution of probabilistic constrained problems. I am sure there will be others which will prove equally or more important in this respect in the future. Chapter 12 describes the basic fact concerning the model: two-stage programming under uncertainty, also called: stochastic programming with recourse. The most important solution techniques were collected but many had to be left out. Chapter 13 discusses the basic ideas about multi-stage stochastic programming problems. This type of problems is very important and attracts great interest but, in almost all cases we arrive at a very large problem; thus, only a few periods can be taken into account, otherwise we cannot solve the problem. More new results are urge~tly needed in this area to satisfy the demand of practice. Preface xi In Chapter 14 we present a selection of some special applied problems. Some of them are network type problems and we may expect wide applicability for them in the future. Finally, Chapter 15 is devoted to distribution problems in stochastic programming. This area is also rapidly developing, especially the analysis of stochastic combinatorial optimization problems is under intensive investigation. A sample also from these problems was taken. Properties of the multivariate normal distribution are frequently used in the book, therefore I felt it useful to include an appendix about it. Except for Chapters 7, 13, and 14, all chapters are supplemented by Excersises and Problems sections. For about twenty years I have been teaching stochastic programming at the mas ter's curriculum on operations research (as a specialised applied mathematical cur riculum) at the Lorand Eotvos University of Budapest, Hungary and at the Ph.D. program on operations research at Rutgers University of the United States of Amer ica. For those who intend to teach it at a master's or Ph.D. level, I recommend material for a one semester course. The materials for the master's and Ph.D. courses can be the same but more proofs should be given to Ph.D. students. Description of a one semester course material: 14 sessions, circa 3 hours each. (1) Some basic statistical decision theoretic models, chosen from Chapter 7; formu lation and solution of the newsboy problem. (2) Overview of the static stochastic programming model constructions as described in Chapter 8. (3) Presentation of the simple recourse problem and its reformulations for the case of discrete random variables; the use of the 6- and A-representations and the main ideas of the relevant solution techniques; the case of the uniform distribution. Use Chapter 9. (4) Basic facts on logconcavity, Sections 4.1-4.4, 10.1-10.2. (5) Chapter 5 with emphasis on the discrete moment problems. (6)-(7) Sections 6.1, 6.2, 6.5, 6.7, 6.8, and Chapter 1I. (8)-(10) Chapter 12. (11) Chapter 13. (12) Sections 15.1-15.2, 15.5, and if we have time, the main result of Section 15.6. (13)-(14) Applications from Chapter 14. If we have a two semester course, then the above material can be presented in more detailed form, more solution techniques can be included from Chapter 11, and Chapter 13, Chapter 15 can almost entirely be included. In addition, the instructor may require that the students should present at class articles from recent literature. The book is the result of about 10 years of work. Similarly as my fellow stochastic programmers feel when they finish a book written on the field, I am also not sure if I solved the book-writing problem in a near optimal way. I am sure, however, that the book will be useful for students and r~~earchers in operations research, statistics, mathematics, and various fields of engineering, economics and other sciences. I wish to express my thanks to RUTCOR, Rutgers University and partly the Air Force! for supporting the writing of the book. My thanks should also be expressed to those who read the manuscript and helped to correct the large number of errors: Ke mal Giirsoy, Olga Fiedler, Lorant Porkolab and Jianmin Long of RUTCOR, Rutgers IGra.nt numbers: AFORS-89-0512B, F49620-93-1-0041