MILITARY OPERATIONS RESEARCH: Quantitative Decision Making INTERNATIONAL SERIES IN OPERATIONS RESEARCH & MANAGEMENT SCIENCE FrederickS. Hillier, Series Editor DepartmentofOperations Research Stanford University Stanford, California Saigal, Romesh The UniversityofMichigan LINEARPROGRAMMING: A Modern IntegratedAnalysis Nagurney, AnnalZhang, Ding UniversityofMassachusetts@Amherst PROJECTEDDYNAMICALSYSTEMSAND VARIATIONAL INEQUALITIES WITHAPPLICATIONS Padberg, ManfrediRijal, MinendraP. NewYorkUniversity LOCATION, SCHEDULING, DESIGNANDINTEGER PROGRAMMING Vanderbei, RobertJ. PrincetonUniversity LINEARPROGRAMMING: FoundationsandExtensions MILITARY OPERATIONS RESEARCH : Quantitative Decision Making N. K. JAISWAL Springer Science+Business Media, LLC Library of Congress Cataloging-in-Publication Data Jaiswal, N. K. Military operations research : quantitative decision making / N. K. Jaiswal. p. cm. --(International series in operations research & management science ; 5) Includes bibliographical references and index. ISBN 978-1-4613-7880-8 ISBN 978-1-4615-6275-7 (eBook) DOI 10.1007/978-1-4615-6275-7 1. Military art and science--Decision making--Mathematical models. 2. Operations research. 1. Title. II. Series. VI 04.134 1997 355.4--dc21 96-53961 CIP Copyright © 1997 by Springer Science+Business Media New York Originally published by Kluwer Academic Publishers in 1997 Softcover reprint of the hardcover 1s t edition 1997 AII rights reserved. No part of this publication may be reproduced, stored in a retrieval system or transmitted in any form or by any means, mechanical, photo copying, recording, or otherwise, without the prior written permission of the publisher, Springer Science+Business Media, LLC Printed an acid-free paper. CONTENTS Preface ix Acknowledgments xi 1 OPERATIONS RESEARCH IN DEFENSE 1 1.1 The Need forOperations Research in Defense 1 1.2 The Birth of OR 2 1.3 MilitaryOR 5 1.4 MethodologyofOR Analysis 6 1.5 Success ofaMilitaryOR Study 10 2 SEARCH, DETECTION AND DAMAGE ASSESSMENT 13 2.1 TargetAcquisition, Engagementand Damage Assessment 13 2.2 DetectionTheory 15 Sensors 15 DetectionModels 16 DetectionModelsfor RadarandSonar 17 2.3 Search Models 19 TargetDistribution,Lateral Rangeand SweepWidth 20 Random and ExhaustiveSearch 21 OptimalSearchStrategy 24 Localization andTracking 25 Identification and Recognition 28 2.4 HitProbability 28 DistributionofErrors 29 Circular,Rectangularand EllipticTargets 30 2.5 Damage Assessment 38 PointTargets 39 AreaTargets 42 2.6 Salvo and Pattern Firing 47 2.7 SingleVs. MultipleAiming Point 52 2.9 Shooting Tactics Based on Damage Information 53 3 SIMULATION OF MILITARYSYSTEMS 59 3.1 System, Model and Simulation 59 VI 3.2 Monte Carlo Sampling Procedure 60 AreaDamaged by BombsorShells 61 3.3 Continuous System Simulation 65 3.4 Discrete System Simulation 66 HitProbabilityofaGunagainstaCircularTarget 68 SurvivabilityofaTank 69 AchievableHitProbability from aTankGun 74 AnAirDefenseNavalEngagement 77 3.5 Weapon System Simulation Vs. Combat Simulation 81 3.6 Simulation Packages 83 4 WAR GAMES 91 4.1 Combat Simulations, WarGames and Theoryof Games 91 4.2 HistoryofWarGames 92 4.3 Classification ofWarGames 93 4.4 Development ofWarGames 96 4.5 Land WarGames 102 4.6 Naval WarGames 105 4.7 AirWarGames 106 4.8 OtherWarGames 107 5 COSTEFFECTIVENESSANALYSIS 111 5.1 Effectiveness and System Cost 111 5.2 Cost Effectiveness Using Fixed EffectivenessApproach 112 5.3 Cost Effectiveness Using Figure of Merit 116 CostEffectivenessofAirDefenseGunsand Surface-to-AirMissiles 117 CostEffectivenessofAir-to-SurfaceMissilesandBombs 121 5.4 Fallacies of Cost Effectiveness Analysis 124 5.5 Cost and Operational Effectiveness Analysis (COEA) 125 6 OPTIMIZATION PROBLEMS 129 6.1 Resource Allocation Problems 129 6.2 Linear Programming 130 TheWeaponMixProblem 132 WeaponDeploymentProblem 134 Weapon TargetAllocation Problem 137 SortieAllocationProblem 137 AirliftProblem 139 6.3 The Transportation Problem 142 6.4 The Assignment Problem 144 6.5 IntegerProgramming 145 146 GomoryCuttingPlaneMethod 148 BranchandBound Method vii 6.6 Multiobjective Programming 151 6.7 Dynamic Programming 152 6.8 NonlinearProgramming 158 6.9 Applications ofOptimization Techniques in Gulf War 165 7 HEURISTICOPTIMIZATION 169 7.1 HeuristicOptimization Algorithms 169 7.2 Weapon Target Allocation Problem in Multiple LayerDefense 169 7.3 Simulated Annealing 172 7.4 Genetic Algorithm 179 7.5 Artificial Neural Networks 184 Cohen-GrossbergTheorem 186 TheContinuous Hopfield Neural NetworkModel 187 OptimizationUsingNeural Networks 188 7.6 Salient Features ofthe Three HeuristicOptimizationTechniques 205 8 THE ANALYTIC HIERARCHYPROCESS 209 8.1 Multicriteria Decision Making 209 8.2 Delphi Method 209 8.3 Decision MatrixApproach 210 8.4 Forced Decision MatrixApproach 211 8.5 Analytic Hierarchy Process 213 Prioritization ofAirborneSurveillanceSystems 216 EvaluatingPerformanceofTanks 224 ProjectSelection 225 8.6 Problems and Modifications of AHP 227 9 HOMOGENEOUS COMBAT MODELS 233 9.1 Lanchester Equations ofWarfare 233 9.2 OtherAttrition Laws 238 9.3 CombatTermination Rules 243 9.4 Measure of Combat Success 246 9.5 Combat Modeling with Spatial Effects 260 9.6 Stochastic Duels 268 9.7 Stochastic Combat Models 270 9.8 Combat Models with NonlinearEffects 276 9.9 Airand Naval Combat Models 277 10 HETEROGENEOUS COMBAT MODELS 283 10.1 The (m,n) model 283 FireAllocationPolicies 284 Solutionofthe(m,n)Model 284 Vlll 10.2 Aggregation 287 10.3 Scaling Methods 290 10.4 An Alternative Approach to Aggregation 293 10.5 Variable Resolution Models 296 10.6 Optimization Models 298 ApplicationofOptimizationModels toStudy Weapon Dominance 305 ApplicationofOptimization Models toStudyWeaponIntroduction 306 11 THREAT ASSESSMENT: STATIC AND DYNAMIC ANALYSES 311 11.1 Threat Assessment 311 11.2 StaticAnalysis 312 BeanCountMethod 313 Weapon EffectivenessIndex(WEI)/WeaponUnitValue(WUV) 313 Potential Anti-PotentialMethod 315 ForcePotential UsingOperational LethalityIndices (OUs) 317 Situationally ModifiedForceStrength (SMFS)Method 322 11.3 Dynamic Analysis 328 QuantifiedJudgmentMethodofAnalysis(QJMA) 328 SituationalForceScoring(SFS) 333 Adaptive DynamicModel 342 Arms Race Models 351 12 ANALYSIS OFSTRATEGIC STABILITY ISSUES 355 12.1 Concept of Stability 355 12.2 Measureof MilitaryStability 357 12.3 Linear Defense Models of Stability 359 StationaryLinearDefenseModel 360 MobileLinearDefenseModel 363 12.4 Stable Regional Force Ratio Model 365 Analytical StabilityModel (ASAM) 366 GeneralizedForceRatioModel (GEFRAM) 369 12.5 Methods for Enhancing Stabilityinthe Region 371 Author Index 373 SUbject Index 379 PREFACE Operations Research (OR) emerged in an effortto improve the effectiveness of newly inducted weapons and equipment during World War II. While rapid growthofORledto itsbecomingan importantaidto decision making in all sectors including defense, its contribution in defense remained largely confined to classified reports. Very few books dealing with applications of quantitative decision making techniques in military have been published presumably due to limitedavailabilityofrelevantinformation. The situation changedrapidly during the last few years. The recognition ofthe subject of Military Operations Research (MOR) gave tremendous boost to its development. Books and journals on MOR started appearing. The number of sessions on MOR at national and international conferences also registered an increase. The volume of teaching, training and research activities in the field of MORatmilitaryschoolsandnon-militaryschoolsenhancedconsiderably. Military executives and commanders started taking increasing interest in getting scientific answers to questions pertaining to weapon acquisition, threat perception and quantification, assessment of damage or casualties, evaluation of chance of winning a battle, force mix, deployment and targeting ofweapons against enemy targets, war games and scenario evaluation. Most of these problems were being tackled on the basis ofintuition, judgment and experience or analysis under very simple assumptions. In an increasingly sophisticatedand complex defense scenario resulting in advances in equipment and communications, the need for supplementingthesepracticesbyscientificresearch inMORbecameimperative. Due to the above reasons, the need of preparing a book on MOR, useful for institutions and OR groups in the Ministry of Defense, service organizations, defense consultancy and research organizations, military schools and universities involved in teaching and research in MOR, was strongly felt. This book is primarilywritten for those interested in learningthe applicationsofORtechniques to solve military problems. It also discusses theoretical concepts needed for analysis of military issues both at tactical and strategic levels. The research scholars in the area ofMOR may also find it useful for their research work as it contains a comprehensive bibliography. An elementary knowledge of OR and ComputerScienceispresumed. A brief preview ofthe book is as follows: Chapter I presents the origin and methodology of OR, need for MOR and factors relevant in a MOR study. x Chapter 2 discusses search, detection and damage assessment. These topics, generally discussed separately, have been merged in one chapter to provide the reader with the basic concepts and formulae needed in subsequent chapters. Chapter 3 discusses discrete and continuous system simulation and illustrates the methodology through a number of examples relevant to military systems. A number of packages useful for combat simulation have been briefly discussed. Chapter 4 extends the idea ofsimulation to design and development ofwar games and briefly discusses a number of software packages. Chapter 5 deals with the methodology of Cost Effectiveness Analysis and also Cost and Operational Effectiveness Analysis. Chapter 6 illustrates a number ofoptimization techniques such as Linear Programming, Integer Programming, Multiobjective Programming, Dynamic Programming and Nonlinear Programming. The examples considered in this chapterrelateto mission planningand logisticsmanagement. Chapter7covers heuristic optimization techniques such as Simulated Annealing, Genetic Algorithm and Artificial Neural Networks. Chapter 8 deals with Analytic Hierarchy Process for ranking and shortlisting ofalternatives orcourses ofaction in situations where qualitativeevaluationofalternatives isonly possible. Chapters9and 10deal with homogeneous and heterogeneous combat models. Chapter 11 discusses a number ofstatic techniques for force potential evaluation such as Weapon Effectiveness Index (WEI)/Weapon Unit Value (WUV), Potential Anti-Potential method and Situationally Modified Force Strength. It also discusses dynamic models such as Quantified Judgment Method of Analysis (QJMA), Situational Force Scoring (SFS), Adaptive Dynamic Model (ADM) and Arms Race Model. Finally, Chapter 12 extends the methodology of threat analysis discussed in Chapter 11 to the analysisofregionalstabilityand itsrelevancetothemultipolarworld. A number of examples have been solved in each chapter to illustrate the application ofthe techniques ofMOR to military systems. The data used in these examples are hypothetical. These do not correspond to any existing weapon or military situation since the purpose is to illustrate the application of MOR in defense decisionmakingratherthan actual problem solving. It is hopedthatthe bookwill promote further researchand applicationsof MOR techniquesto defensedecisionmaking. A-2/28, Janakpuri N. K. Jaiswal New Delhi-I10058, India