fP t)NaS ES ARCH -:C E E R t: ::- ::!d !' 0i --0iD ;fff 0 ;0tt ...Fd ff~ ~~~t~ ~~~~-::~ ~~_~;: ~f~i0~*0~ 0j 00000 i tV aS ::-:: ;. :o . : : : : :. -:' :- ; _i t :t Si . a':0 000.ff~ff .,: ; ,:: .:~:~:I:·i '- .::::·:;:-:b .. ... . . . .. , "' ' ', ' .'' , ' -' ' ' @ .' '. ' ' ' ' ' ' ' D ' ' ' ,' ' ' '' ' , " ." ",. ,: ' ',0000S~0'~0 ~~ ~ ;0f~f X0f~X~f7~L 0 ~~~~~~~w 0D VQ ;'il= M0t,5:00;t< 000 0 ,; 0 ;, ". _ ' .' ' '' "' '; ' ... . - ' ......... . ' -" _ -'''5 ''S.'. l','m", .',' '''.'- ,. . . *XAZ-~~~~~~~~~~~~~~~~~~~~~~ · :a :::-,- ;- : ---: t- . . ----. .:: ~~ ~ ;: .;'>7-i :: * ,' ' ' ' -,'r i g' ,,'aper-'. . j .,t ,; ,: 7; , ,, .~~~~~ . , . : , . . . ..:-.; - .. - ·:. ;..·.· . -··-·;··· r·-·': `._;'·:. ·--. ; ·. · -i· ·-· (cid:3). :e 1; . ··i: :· ;·"·:-::... _-.-;-I-. s· :? i. . I --·.-- '-:.. 1L MASNSSTc ITUITE: $;- 502S9: Xt4-7;t$5i 0-9:00N Network Flows by Ravindra K. Ahuja, Thomas L. Magnanti and James B. Orlin OR 185-88 August 1988 ma NETWORK FLOWS Ravindra K. Ahuja* , Thomas L. Magnanti, and James B. Orlin Sloan School of Management Massachusetts Institute of Technology Cambridge, MA. 02139 * On leave from Indian Institute of Technology, Kanpur - 208016, INDIA I il NETWORK FLOWS OVERVIEW 1. Introduction 1.1 Applications 1.2 Complexity Analysis 1.3 Notation and Definitions 1.4 Network Representations 1.5 Search Techniques 1.6 Developing Polynomial Time Algorithms 2. Basic Properties of Network Flows 21 Flow Decomposition Properties and Optimality Conditions 22 Cycle Free and Spanning Tree Solutions 2.3 Networks, Linear and Integer Programming 2.4 Network Transformations 3. Shortest Path Problems 3.1 Dijkstra's Algorithm 3.2 Dial's Algorithm 3.3 R-Heap Implementation 3.4 Label Correcting Algorithms 3.5 All Pair Shortest Path Algorithm 4. Maximum Flow Problem 4.1 Labeling Algorithm and the Max-Flow Min-Cut Theorem 4.2 Decreasing the Number of Augmentations 4.3 Shortest Augmenting Path Algorithm 4.4 Preflow-Push Algorithms 4.5 Excess-Scaling Algorithm 4.6 Networks with Positive Lower Bounds S. Minimum Cost Flow Problem 5.1 Optimality Conditions 52 Relationship to Shortest Path and Maximum Flow Problems 5.3 Negative Cycle Algorithm 5.4 Successive Shortest Path Algorithm 5.5 Primal-Dual and Out-of-Kilter Algorithms 5.6 Network Simplex Algorithm 5.7 Right-Hand-Side Scaling Algorithm 5.8 Cost Scaling Algorithm 5.9 Double Scaling Algorithm 5.10 Sensitivity Analysis 5.11 Assignment Problem Reference Notes References so. 1 Network Flows Perhaps no subfield of mathematical programming is more alluring than network optimization. Highway, rail, electrical, communication and may other physical networks pervade in our everyday lives. As a consequence, even non-specialists recognize the practical importance and the wide ranging applicability of networks. Moreover, because the physical operating characteristics of networks (e.g., flows on arcs and mass balance at nodes) have natural mathematical representations, practitioners and non-specialists can readily understand the mathematical descriptions of network optimization problems and the basic nature of techniques used to solve these problems. This combination of widespread applicability and ease of assimilation has undoubtedly been instrumental in the evolution of network planning models as one of the most widely used modeling techniques in all of operations research and applied mathematics. Network optimization is also alluring to methodologists. Networks provide a concrete setting for testing and devising new theories. Indeed, network optimization has inspired many of the most fundamental results in all of optimization. For example, price directive decomposition algorithms for both linear programming and combinatorial optimization had their origins in network optimization. So did cutting plane methods and branch and bound procedures of integer programming, primal-dual methods of linear and nonlinear programming, and polyhedral methods of combinatorial optimization. In addition, networks have served as the major prototype for several theoretical domains (for example, the field of matroids) and as the core model for a wide variety of min/max duality results in discrete mathematics. Moreover, network optimization has served as a fertile meeting ground for ideas from optimization and computer science. Many results in network optimization are routinely used to design and evaluate computer systems, and ideas from computer science concerning data structures and efficient data manipulation have had a major impact on the design and implementation of many network optimization algorithms. The aim of this paper is to summarize many of the fundamental ideas of network optimization. In particular, we concentrate on network flow problems and highlight a number of recent theoretical and algorithmic advances. We have divided the discussion into the following broad major topics: 2 * Applications * Basic Properties of Network Flows * Shortest Path Problems Maximum Flow Problem * Minimum Cost Flow Problem * Assignment Problem Much of our discussion focuses on the design of provably good (e.g., polynomial) algorithms. Among good algorithms, we have presented those algorithms which are simple and are likely to be efficient in practice. We have attempted to structure our discussion so that it not only provides a survey of the field for the specialists, but also serves as an introduction and summary to the non-specialists who have a basic working knowledge of the rudiments of optimization, particularly linear programming. As a prelude to our discussion in the next section, we present in this section several important preliminaries . We discuss (i) different ways to measure the performance of algorithms; (ii) graph notation and various ways to represent networks quantitively; (iii) a few basic ideas from computer science that underlie the design of many algorithms; and (iv) a couple of generic proof techniques that have been useful in designing polynomial algorithms. 1.1 Applications Networks arise in numerous application settings and in a variety of guises. In this section, we briefly describe a few prototypical applications. Our discussion is intended to illustrate a range of applications and to be suggestive of how network flow problems arise in practice; a more extensive survey would take us far beyond the scope of our discussion. To illustrate the breadth of network applications, we consider some models requiring solution techniques that we will not describe in this chapter. For the purposes of this discussion we will consider four different types of networks arising in practice: · Physical networks (Streets, railbeds, pipelines, wires) · Route networks · Space-time networks (Scheduling networks) · Derived networks (Through problem transformations)