An overview of nontraditional formulations of static and dynamic equilibrium network design

This paper reviews two classes of nontraditional models for the (dis)equilibrium network design problem and uses these to describe research needed to advance the state-of-the art in the design of both static and dynamic networks. The static equilibrium design model emphasized herein recalls an important earlier result that allows the equilibrium network design problem to be stated as a single level mathematical program (SMP), a result which is surprisingly little known; it also introduces for the first time nonseparable elastic transportation demands and attendant difficulties in evaluating the consumers' surplus line integral. The dynamic, disequilibrium network design model emphasized herein maintains the usual design objective of maximizing some measure of social welfare, but recognizes that traffic on a network is not necessarily in equilibrium and that capacity changes to the network must induce transient phenomena not captured by invocation of the static version of Wardrop's first principle (user equilibrium). It is argued that such disequilibrium models by their very nature avoid temporal versions of Braess' paradox familiar from static equilibrium design and are naturally formulated as optimal control problems. Moreover, properly formulated disequilibrium design models are shown to overcome difficulties associated with evaluating the consumers' surplus line integral. Furthermore, when the associated disequilibrium dynamics are stable, these optimal control formulations are observed to be capable of computing static equilibrium network designs.

[1]  Terry L. Friesz,et al.  Dynamic Systems, Variational Inequalities and Control Theoretic Models for Predicting Time-Varying Urban Network Flows , 1996, Transp. Sci..

[2]  Steven G. Louie,et al.  A Monte carlo simulated annealing approach to optimization over continuous variables , 1984 .

[3]  J. G. Wardrop,et al.  Some Theoretical Aspects of Road Traffic Research , 1952 .

[4]  C. D. Gelatt,et al.  Optimization by Simulated Annealing , 1983, Science.

[5]  Hai Yang,et al.  Models and algorithms for road network design: a review and some new developments , 1998 .

[6]  Anna Nagurney,et al.  Dynamical systems and variational inequalities , 1993, Ann. Oper. Res..

[7]  H. Kunzi,et al.  Lectu re Notes in Economics and Mathematical Systems , 1975 .

[8]  J. Wardrop ROAD PAPER. SOME THEORETICAL ASPECTS OF ROAD TRAFFIC RESEARCH. , 1952 .

[9]  Ramesh Sharda,et al.  Impacts of recent computer advances on operations research , 1989 .

[10]  T. Friesz,et al.  MEASURING THE BENEFITS DERIVED FROM A TRANSPORTATION INVESTMENT. IN: URBAN TRANSPORT , 1982 .

[11]  T. Friesz,et al.  The multiobjective equilibrium network design problem revisited: A simulated annealing approach , 1993 .

[12]  Michael Athans,et al.  HYBRID OPTIMIZATION IN URBAN TRAFFIC NETWORKS , 1979 .

[13]  Terry L. Friesz Multiobjective Optimization in Transportation: The Case of Equilibrium Network Design , 1981 .

[14]  Terry L. Friesz,et al.  Disequilibrium Network Design: A New Paradigm for Transportation Planning and Control , 1998 .

[15]  Terry L. Friesz,et al.  A Simulated Annealing Approach to the Network Design Problem with Variational Inequality Constraints , 1992, Transp. Sci..

[16]  Terry L. Friesz An equivalent optimization problem for combined multiclass distribution, assignment and modal split which obviates symmetry restrictions , 1981 .