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Abstract

This paper presents a computable general equilibrium model of a stylized linear city that simultaneously minimizes transportation costs while satisfying labor, and, and goods equilibrium conditions, in the tradition of Anas and Kim, while introducing a monetary balance. This model has structural similarity with Davis's design of an optimal transportation system under user equilibrium conditions. The model includes three industries: manufacturing, retail, and services. Their economic transactions are empirically modeled using national input–output data, which allows for the endogenous determination of import and export pricing and flows. Numerical applications show that more efficient transportation increases utility and leads to a centralization of the population, and that zoning, under various restriction scenarios, decreases utility, with the most detrimental effects on residents in unrestricted zones. Finally, a zero trade deficit scenario results in lower utility, a larger transportation system, and smaller residential lots, with higher CBD population density.

Keywords

computable general equilibrium land use and transportation regional planning trade zoning input–output data

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References

Abdel-Rahman

Fujita

, 1990, “Product variety, Marshallian externalities, and city sizes” Journal of Regional Science 30 165–183.

Anas

Kim

, 1996, “General equilibrium models of polycentric urban land use with endogenous congestion and job agglomeration” Journal of Urban Economics 40 232–256.

Anas

Liu

, 2007, “A regional economy, land use, and transportation model (RELU_TRAN®): Formulation, algorithm design, and testing” Journal of Regional Science 47 415–455.

Anas

Rhee

, 2006, “Curbing excess sprawl with congestion tolls and urban boundaries” Regional Science and Urban Economics 36 510–541.

Anas

, 1999, “Congestion, land use, and job dispersion: A general equilibrium model” Journal of Urban Economics 45 451–473.

Berliant

Zenou

, 2002, “Labor differentiation and agglomeration in general equilibrium”, mimeo, Department of Economics, Washington University, University of Southampton.

BPR, 1964 Traffic Assignment Manual Bureau of Public Roads, US Department of Commerce, Washington, DC.

Brasington

, 2001, “A model of urban growth with endogenous suburban production centers” The Annals of Regional Science 35 411–430.

Davis

, 1994, “Exact local solution of the continuous network design problem via stochastic user equilibrium assignment” Transportation Research B 28 61–75.

10.

Federal Highway Administration, Office of Highway Policy Information, 2009 Vehicle Travel Information System, http://apps.fhwas.dot.gov/VTRIS/report.aspx.

11.

Fisch

, 1975, “Externalities and the urban rent and population density function: The case of air pollution” Journal of Environmental Economics and Management 2 18–33.

12.

Fujita

Krugman

Venables

, 1999 The Spatial Economy: Cities, Regions, and International Trade (MIT Press, Cambridge, MA).

13.

Gordon

Richardson

Wong

, 1986, “The distribution of population and employment in a polycentric city: The case of Los Angeles” Environmental and Planning A 18 161–173.

14.

Hartwick

, 1974, “Efficient resource allocation in a multinucleated city with intermediate goods” The Quarterly Journal of Economics 88 340–352.

15.

Lucas

Rossi-Hansberg , 2002, “On the internal structure of cities” Econometrica 70 1445–1476.

16.

McDonald

, 1989, “Econometric studies of urban population density: A survey” Journal of Urban Economics 26 361–385.

17.

McMillen

, 2004, “Employment densities, spatial autocorrelation, and subcenters in large metropolitan areas” Journal of Regional Science 44 225–243.

18.

McMillen

McDonald

, 1998, “Suburban subcenters and employment density in metropolitan Chicago” Journal of Urban Economics 43 157–180.

19.

Mills

, 1967, “Transportation and patterns of urban development: An aggregative model of resource allocation in a metropolitan area” American Economic Review 57 197–210.

20.

Mills

de Ferranti

, 1971, “Market choices and optimum city size” American Economic Review 61 340–345.

21.

Mohring

Hartwitz

, 1962 Highway Benefits: An Analytic Framework (Northwestern University Press, Chicago, IL).

22.

Morris

Kornhauser

Kay

, 1998, “Urban freight mobility: Collection of data on time, costs and barriers related to moving product into the central business district” Transportation Research Record number 1613, 27–32.

23.

Olwert

, 2010 A Computable General Equilibrium Model of the City with Optimization of its Transportation Network: Impacts of Changes in Technology, Preferences, and Policy PhD dissertation, City and Regional Planning, The Ohio State University, Columbus, OH.

24.

Sasaki

Mun

, 1996, “A dynamic analysis of multiple-center formation in a city” Journal of Urban Economics 40 257–278.

25.

Smith

, 1997, “A review of monocentric urban density analysis” Journal of Planning Literature 12 (2) 115–135.

26.

Sullivan

, 1986, “A general equilibrium model with agglomeration economies and decentralized employment” Journal of Urban Economics 20 55–74.

27.

Verhoef

Nijkamp

, 2008, “Urban environmental externalities, agglomeration forces, and the technological ‘deus ex machina’” Environment and Planning A 40 928–947.

28.

Wheaton

, 2004, “Commuting, congestion, and employment dispersal in cities with mixed land use” Journal of Urban Economics 55 417–438.

29.

Zhang

Sasaki

, 1997, “Effects of subcenter formation on urban spatial structure” Regional Science and Urban Economics 27 297–324.

A Computable General Equilibrium Model of the City: Impacts of Technology,Zoning,and Trade

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