regional economic impacts of highway...
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Regional Economic Impacts of Highway Projects*
Mark Roberts1, Uwe Deichmann2, Bernard Fingleton3,
Tuo Shi1, and Andreas Kopp4
VERY PRELIMINARY DRAFT – not for citation
September 2009
1 Department of Land Economy, University of Cambridge 2 Development Research Group, World Bank
3 Department of Economics, University of Strathclyde 4 Energy, Transport and Water Department, World Bank
* This paper presents preliminary results from a research project that is supported by the Research Support Budget of the World Bank. The findings, interpretations, and conclusions expressed in this paper are entirely those of the authors. They do not necessarily represent the views of the International Bank for Reconstruction and Development/World Bank and its affiliated organizations, or those of the Executive Directors of the World Bank or the governments they represent.
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Regional Economic Impacts of Highway Projects
Abstract
Interregional transport infrastructure represents some of the largest public investment programs in developing countries. The objectives are typically to increase economic efficiency—overall economic growth—as well as spatial equity—helping lagging areas of a country to catch up with leading ones. But recent theoretical and empirical work on the ‘new economic geography’ suggests that, at least initially, lowering transport costs may reinforce concentration of economic activity. This paper describes ongoing research, building on the work by Krugman and others, to develop a geographically explicit framework for assessing the impacts of large scale transport investments on regional economies. The goal is to develop tools for ex-ante impact evaluation that complement macro-economic approaches as well as engineering-oriented operational practice. We illustrate our approach with an application to China’s massive expansion of highways, the National Expressway Network (NEN).
1. Introduction
Each year, governments around the world devote considerable expenditure to transport
infrastructure projects designed to improve connectivity between leading and lagging
regions—partly in the belief that this will bring large aggregate benefits and partly in the
belief that it will promote inter-regional economic convergence. In the European Union
(EU), for instance, considerable investment is being directed towards the development of
a Trans-European Transport Network (TEN-T) which is designed to, inter alia, bolster
competitiveness and promote economic and social cohesion (Bröcker, 2002).
Likewise, several large developing countries have recently committed significant funds to
the expansion of national transportation networks with similar objectives in mind. The
most visible has been China, where massive expenditure on the construction of a 41,000
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km National Expressway Network (NEN) has constituted a central plank of the
government's "Go West" initiative, which is intended to help narrow regional inequalities
which have emerged over the last three decades as a result of the spectacular growth of
the country's coastal provinces.1 Between 1990 and 2005, China spent approximately
US$ 40 billion annually on the building of roads—about a third of which has gone
towards the NEN. Meanwhile, India is nearing the completion of its US$ 13 billion
"Golden Quadrilateral"2, a 5,846 km network of 4-6 lane expressways which constitutes
the first phase of the country's National Highways Development Project. The Brazilian
government intends to spend, by 2010, US$ 17 billion on upgrading its expressways as
part of a US$ 250 billion infrastructure program.3 Finally, international donors recently
committed US$ 1 billion for the "North-South Corridor", an initiative in east and
southern Africa which will result in the eventual upgrade of 8,000 km of roads.4
Major inter-regional transportation projects such as those outlined above are frequently
pursued with the twin objectives of achieving both increased efficiency and spatial
equity: that is to say, of both increasing productivity and well-being at the national level,
as well as of increasing the equity of economic outcomes across space. However, new
theories of the determinants of the spatial distribution of economic activity and well-
being (the so-called "new economic geography", or NEG, literature) which have emerged
1 In 2005, the leading provincial level region of Shanghai had a level of GDP per capita that was 3.34 times the national average, while the poorest performing region of Guizhou had a level that was only 0.34 times the national average (The World Bank, 2008, chp. 2). 2 So-called because it connects Delhi, Mumbai, Kolkata and Chennai, thereby forming a quadrilateral of sorts. 3 “Global Perspectives: Brazil's Highway Headaches”, Blueprint America (www.pbs.org), October 26th, 2008. 4 “New dawn for trade in Africa as UK Government commits to North South Corridor”, UK Department for International Development (DFID), 06 April 2009.
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over the last two decades5 imply that the benefits of large scale infrastructure investments
may not always manifest themselves in ways anticipated by policymakers.
Far from promoting convergence through stimulating the relocation of firms to lagging
regions, these theories suggest that the resulting transport cost reductions may well
encourage increased agglomeration in the already leading regions at the expense of the
lagging ones, thereby engendering increased regional divergence. The main driver of
these dynamics is the existence of internal economies of scale, which interact with both
transport costs and factor mobility to generate potentially powerful agglomeration
economies (at least in some sectors of the economy). Reducing transport costs affects the
relative strengths of both agglomeration and dispersion forces, and, therefore, the spatial
distribution of economic activity. As such, there exists the possibility of a trade-off
between efficiency (towards which agglomeration may make a contribution) and spatial
equity.
This gives rise to two main policy questions relating to large scale transportation
investments. The first is the standard CBA question regarding efficiency: Do these
investments generate economic and welfare benefits that outweigh their (significant)
costs? If there are winners and losers, are the gains sufficient to compensate the losers—
either through some form of redistributive mechanism or, for instance, by encouraging
labor mobility and remittances? The second question addresses the issue of spatial
equity: do improvements in inter-regional transportation infrastructure tend to spread-out 5 See Brakman et al. (2009) and Fujita et al (1999) for comprehensive reviews.
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economic activity and thus predominantly benefit lagging areas as is frequently the
intention of policymakers? Or, do they lead to further concentration as firms in leading
areas that benefit from greater agglomeration economies take advantage of lower
transport costs to expand exports into lagging areas and as workers gravitate in ever-
increasing numbers to areas of already existing prosperity?
This paper reports on ongoing research to improve our ability to answer these policy
questions, specifically in a developing country context. By using an NEG framework
that captures the spatial general equilibrium effects of changes in transport costs, we aim
to expand the impact evaluation toolbox beyond macro-analysis of infrastructure benefits
(such as those based on Aschauer 1989), as well as beyond operational practice that tends
to focus on benchmarks such as travel time reductions, vehicle operating costs and
avoided accidents.6 In particular, we consider the benefits of adopting an NEG approach
to evaluating infrastructure benefits vis-à-vis other approaches; outline a methodology for
the operationalization of NEG theory for this purpose; and present some early results
based on the construction of China's NEN. Given that this research is still in its formative
stages, our application to China is, at this point, primarily intended to illustrate
methodology. We intend to fully develop this application over the next three months and,
in the concluding section of this paper, discuss the issues which need to be confronted to
do so.
6 Such as those supported by the Highway Development and Management Model HDM4 (www.worldbank. org/transport/roads/rd_tools/hdm4.htm).
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Our project is not the first to draw on NEG theory, or elements of it, in an attempt to
build operational models for the purposes of evaluating the benefits of major
transportation projects. But it is the first to do so in a developing country context. A
number of previous studies have estimated the so-called NEG wage equation for China
(Au and Henderson, 2006a; Bosker et al., 2009; Hering and Poncet, 2008, amongst
them), but no previous study has made use of a full structural NEG model to look at the
impacts of transportation infrastructure improvements, drawing upon a detailed
Geographic Information Systems (GIS) data set of the country's road network.
Furthermore, the application to developing countries brings with it unique challenges.
While it is safe to ignore the rural sector when thinking about reductions in transport
costs in the context of developed countries, this sector cannot be ignored in a developing
country context. As such, our application to China makes use of an NEG model
consisting of both an urban and a rural sector, with transport costs in both sectors.
Finally, our methodological approach is unique insofar as the (ultimate) intention is to
combine estimation of key model parameters with simulation of transport infrastructure
improvements using the complete structure of an NEG model, making, in the process, a
distinction between impacts associated with the model's short- and long-run equilibrium
solutions.
The remainder of this paper is organized as follows. In section 2 we provide a brief
introduction to NEG theory, consider the potential "value-added" of adopting an NEG-
based approach to benefit evaluation over and above more traditional approaches, and
address some common reservations to the use of an NEG framework. Section 3 provides
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a broad overview of the methodological approach we are pursuing in our project. In
section 4, we illustrate key aspects of this approach using our (early) application to
China's NEN. The concluding section, section 5, discusses the next steps in making this
illustrative application more concrete.
2. The value added of an NEG approach to benefit estimation
2.1. A quick introduction to NEG theory
Originating with the work of Krugman (1991a, 1991b), the new economic geography
(NEG) represents a body of theory which aims to explicitly model the interplay between
the agglomeration and dispersion forces which shape an economy's internal spatial
distribution of economic outcomes. Although, as pointed out by critics such as Martin
(1999), there is nothing new about many of the ingredients of NEG models, NEG has
nevertheless succeeded in integrating these within a general equilibrium framework
(Ottaviano and Thisse, 2004, p 2576). One of the key ingredients which is common to all
NEG models is the existence of transport costs.7 Thus, for example, in the seminal model
of Krugman, transport costs in the manufacturing sector interact with the fixed costs of
setting-up a plant within the sector and labour mobility to create agglomeration
economies, which take the form of a pecuniary externality. Counteracting the resultant
centripetal force is a centrifugal force associated with the existence of a dispersed, and
immobile, agricultural population. By strengthening the centripetal force relative to the
centrifugal force, falling transport costs can have symmetry breaking results, whereby a
7 More generally, these costs can be interpreted as the costs of conducting transactions at a distance. As such, they may include not only transport costs, but more general trade costs, including costs of acquiring information about products.
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spatially uniform distribution of manufacturing activity no longer represents a stable
equilibrium.
More generally, within NEG theory, declining transport costs change the relative strength
of centripetal and centrifugal forces. In many models, the resultant predicted relationship
between transport costs and the spatial distribution of economic activity is not necessarily
the predictable catastrophic agglomeration of the original Krugman model. Rather, a bell-
shaped relationship between declining transport costs and the spatial concentration of
activity is a characteristic prediction of, for example, the models of Fujita and Krugman
(1995) and Krugman and Venables (1995). According to this relationship, a reduction in
transport costs promotes, at first, widening regional disparities and an increased
agglomeration of activity before eventually inducing convergence and a dispersion of
activity. For a given level of agricultural transport costs, this is also the predicted
relationship between manufacturing transport costs and the spatial distribution of activity
in the two region version of the model (Fujita et al, 1999, chp 7) that we modify and
generalize for application to China in section 4 of this paper.
2.2. Alternative approaches to benefit estimation and what an NEG approach has to add
An NEG-based approach to evaluating the benefits of inter-regional transportation
infrastructure projects needs to be compared against two alternative approaches. The first
is the standard CBA approach which focuses exclusively on the transport market. Thus,
the projected benefits of a project are calculated by measuring the reductions in travel
time, vehicle operating costs and transport related accidents that are the anticipated result
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of a project. In the absence of externalities or market imperfections, transport economics
shows that such benefits accurately capture total project benefits (Wheaton, 1977; see
also Laird et al., 2005, p. 542 and Vickerman, 2000, pp. 15-16). This is because other
benefits, such as favorable land price changes, are apparent rather than real—they are not
distinct benefits, but simply reflections of the transport benefits in other markets (World
Bank, 2006, pp 2-3). Such an approach has the important virtue of being extremely well
tried and tested and, relatively, easy to apply. Consequently, at a policy level, it
constitutes the standard approach towards the ex ante assessment of benefits, especially at
the level of individual projects. However, on the downside, this approach is incapable of
capturing the potential additional benefits that are associated with the knock-on effects of
the travel time reductions induced by a project on the relative strengths of agglomeration
and dispersion forces within an economy, and the subsequent repercussions for the spatial
distribution of economic activity. As we have seen, these forces represent the raison
d'être of NEG theory.
The second approach to evaluating benefits is provided by the macro level empirical
literature. This seeks to establish social rates of return to infrastructure investment
through the estimation of, for example, aggregate production functions which have been
augmented with various measures of infrastructure. In contrast to the standard CBA
approach, this is capable of capturing the additional positive externalities, including the
potential benefits associated with NEG-style forces, which may be associated with major
transportation projects. However, this literature has been plagued by empirical
controversy due to, inter alia, problems of endogeneity and measurement error ever since
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the extremely large estimated elasticities of output with respect to public capital obtained
by Aschauer (1989). The recent review and meta-analysis of this literature by Straub
(2008) highlights the existence of considerable empirical uncertainty of the productivity
and growth effects of infrastructure. Indeed, estimates of benefits have been found to
vary significantly according to the details of the particular sample and estimation
methods used.
Relative to the above approaches, an NEG-based approach to evaluating benefits has the
potential to add value in several respects. Firstly, as already stated, such an approach is
capable of capturing the spatial general equilibrium effects, associated with the changing
strength of agglomeration and dispersion forces, which are assumed away by the standard
CBA approach. Second, because an NEG-based approach is founded on an explicit
spatial general equilibrium framework, it links the potential impacts of projects to key
structural characteristics of an economy, such as the existing level of transport costs in
different sectors, the relative importance of sectors characterized by increasing returns to
scale relative to those characterized by constant returns to scale and the degree of factor
mobility (and, therefore, the size and extent of policy and institutional barriers on labor
mobility, such as those associated with the permanent household registration, i.e. Hukou,
system in China). In this way, an NEG-based approach suggests that the impacts of
projects are likely to be heterogeneous across both countries and time, varying according
to structural conditions. Consequently, an NEG-based approach has the potential to
explain the seemingly contradictory results which exist in the macro level empirical
literature. These contradictions find no explanation within that literature itself because
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estimates from macro level studies represent something of a black box as regards the
causal mechanisms which drive estimated productivity and welfare gains from
transportation infrastructure improvement.
Finally, and related to the previous point, an NEG-based approach has the potential to
capture both the short- and long-run aggregate and spatial economic impacts connected
with a project, where we may associate short-run impacts with a fixed spatial and sectoral
distribution of employment and long-run impacts with additional effects emanating from
labor mobility and migration. It is potentially capable of answering the question of
whether there exists a variable time-profile of impacts on, for example, inequalities
between leading and lagging regions. For example, where a project initially gives rise to
increased inequality in real wages between regions, will migration and labor mobility
eventually arbitrage away such differences or will it exacerbate them?
3.3. Objections to an NEG-based approach
In our consultations to date, we have heard expressed several reservations to the adoption
of an NEG-based approach to benefit evaluation, some of which we share, but believe
can be overcome, and others we regard as misplaced. The concerns which we share relate
primarily to the modelling of transport costs, in particular, their functional form, within
NEG theory. As will become clear, the functional forms for the relationship between
transport costs and travel time which we specify in our application to China are
somewhat ad hoc, so far as empirical justification is concerned, and we also make equally
ad hoc assumptions regarding parameter values for these functional forms. This is one
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reason why this application remains, at this early stage, primarily intended to be
illustrative of some of the key aspects of the methodological approach that we are
pursuing. We shall return to this issue in section 5, as well as covering other challenges
which must be overcome to render our application to China more concrete.
There are two types of reservation that we have encountered, but which we consider to be
misplaced: (1) the reservation that an NEG-based approach must necessarily be biased
towards producing inflated estimates of benefits because of the theory's "assumption" of
agglomeration economies; and (2) reservations regarding the use of a framework reliant
on assumptions of Dixit-Stiglitz monopolistic competition. The first reservation is
relatively easily dealt with. NEG theory does not assume the existence of agglomeration
economies. Rather, such economies are the endogenous outcome of several forces within
NEG models and, depending on the relative strength of such forces, an economy may
find itself, for example, in a scenario characterized by multiple equilibria, some of which
are characterized by agglomeration, or in a scenario in which there is a unique stable
equilibrium with no agglomeration whatsoever. As such, it is perfectly possible, in an
NEG world, for a reduction in transport costs, caused by a major programme of inter-
regional transport infrastructure expenditure, to have no predicted beneficial impacts
above and beyond those considered by a standard CBA exercise. Again, one of the key
lessons of the NEG is that it all depends on key structural parameters within an economy,
which makes the whole issue of agglomeration impacts ultimately an empirical question
which should be guided by appropriate theory.
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The second set of reservations regarding assumptions of Dixit-Stiglitz competition are
ones which have also found a voice in the literature. In particular, Neary (2001) has been
very critical of the NEG for its overwhelming tendency to follow Krugman (1991a,
1991b) in making this assumption. This is because "the Dixit-Stiglitz model has almost
nothing to say about individual firms."8 As a consequence, "except for the fact that it
incorporates increasing returns, the new economic geography has industrial
organization underpinnings which are very rudimentary." (Neary, 2001, p 18). However,
while this might be true, is there a viable alternative to the assumption of Dixit-Stiglitz
competition whose benefits outweigh its costs?
Our answer to the above question is almost certainly not. This is based on a consideration
of the history of economic thought of the Cournot competition literature—Cournot
competition being the alternative market structure assumption to Dixit-Stiglitz
competition which we have heard most frequently suggested. In particular, the Cournot
competition literature emerged as an attempt to respond to the discovery that the
agglomeration equilibrium in the Hotelling model does not exist (d'Aspremont,
Gabszewicz and Thisse, 1979). The reason for this is that even an infinitesimal price cut
by one of the competitors will allow him to capture the entire market. Consequently,
there is a strong incentive for firms to seek protection by distance, which creates a
tendency for the spatial dispersion of industry. Cournot competition overcomes this
problem through the assumptions that there is no market entry in response to positive
8 In particular, the assumption of Dixit-Stiglitz competition sterilizes considerations of direct strategic interaction. However, contrary to common perception, it does not imply the complete absence of interactions between firms- "Indeed, each firm must figure out what will be the total output (or, alternatively, the average price index) in equilibrium when choosing its own quantity or price, or when deciding whether to enter the market." (Ottaviano and Thisse, 2004, p 2578).
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abnormal profits, and that firms renounce to compete in prices. These assumptions
provide firms with sufficient protection that they might want to locate in the same place.
This raises several questions: namely, (i) do firms indeed collude in not competing in
prices? And (ii), do we observe that there is no entry to imperfectly competitive markets
empirically? Not surprisingly, recent reviews of the agglomeration literature (Duranton
and Puga, 2004) either make no mention of the Cournot competition agglomeration
literature or present it purely as part of pre-1990s history of economic thought (Ottaviano
and Thisse, 2004). This is primarily because, in industrial organization research, the
exogenous restriction of firms' strategy space which the Cournot competition model (i.e.
the exogenous restriction of not competing on prices) implies has been rejected. In order
to be able to adopt an alternative approach based on Cournot competition, therefore, it
would be necessary to show that the assumption of Cournot behavior is a game-theoretic
equilibrium.
Furthermore, models based on Cournot competition, are partial equilibrium models; there
are no repercussions on factor markets. There is also an absence of factor mobility and,
therefore, demand. This is in contrast to NEG models based on Dixit-Stiglitz
monopolistic competition. Despite the starkness of the Dixit-Stiglitz assumptions, an
NEG approach based on these appear to be more general than the partial-equilibrium
spatial oligopoly models.9
9 Ottaviano and Thisse (2004, p 2577) note that "Unfortunately, models of spatial competition are plagued by the frequent nonexistence of an equilibrium in pure strategies... Thus, research has faced a modeling trade-off: to appeal to mixed strategies, or to use monopolistic competition in which interactions between firms are weak. For the sake of simplicity, Krugman and most of the economics profession have retained the second option, which is not unreasonable once we address spatial issues at a macro-level. In addition,
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3. Methodology
Previous attempts to operationalize NEG theory, or at least elements of it, for the
purposes of evaluating the benefits of major inter-regional transportation projects have
largely taken the form of the development of Spatial Computable General Equilibrium
(SCGE) models. Most notable amongst these is the EU's development of the CGEurope
model, which it has applied in several projects and reports10 to assess the impacts of
proposed TEN-T projects which aim to better connect lagging European regions with
leading ones. Further examples include the RAEM model, which has been developed for
the Netherlands and applied to the ex ante assessment of a number of proposed magnetic
levitation rail projects (Oosterhaven and Elhorst, 2008). While our approach bears some
resemblance to a SCGE approach, particularly in its use of detailed transportation
network data, it should not be mistaken for such an approach. Rather, our approach builds
more directly on the academic NEG empirical literature. In particular, it builds on
literature which seeks to estimate the so-called NEG wage equation, which is a predicted
relationship, generic to most NEG models, between nominal wages and a measure of a
region's market potential (Au and Henderson, 2006a; Bosker et al., 2009; Brakman et al,
2006; Hering and Poncet, 2008). It also builds on literature which uses a full structural
NEG model to simulate the short-run spatial economic impacts of a generalized reduction
in transport costs, where this reduction is modelled as a change in a scalar parameter
models of monopolistic competition have shown a rare ability to deal with a large variety of issues related to economic geography, which are otherwise unsatisfactorily treated by the competitive paradigm..." 10 These include its IASON (Integrated Appraisal of Spatial Effects of Transport Investments and Policies) project, its EPSON (European Spatial Planning Observation Network) Territorial Impact of EU Transport and TEN Policies project, and its ASSESS report. For an overview of the theory underlying this model see Bröcker (2002).
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which enters into an assumed transport cost function based on straight-line distance
(Brakman et al., 2006; Fingleton, 2005, 2007).
More precisely, the methodology which we are developing consists of two broad stages.
In stage (1), estimates of key NEG model parameters are obtained through estimation of
the NEG-wage equation for different sectors of the economy (e.g. the urban and rural
sectors). Estimation makes use of GIS derived data on minimum travel times for the
transportation network, past or future changes to which we wish to evaluate the impact
of. Meanwhile, in stage (2), a numerical solution is obtained for a full structural NEG
model under a baseline scenario and the fit of this numerical solution to actual regional
economic data is examined. This helps both to provide an assessment of the relevance of
the model, and, therefore, NEG-style forces, to the country under study and to indicate
areas where additional model development might be required. Following this, the
changes to the transportation network which are the subject of evaluation are introduced
and a new numerical solution to the model is obtained. This numerical solution represents
the counterfactual solution. The regional economic impacts of the network changes can
then be assessed by comparing the counterfactual with the baseline solution.11
It is possible to apply the above methodology such that the baseline scenario corresponds
to either the situation prior to or following the period over which the infrastructure
investment has taken place. Furthermore, it is possible to simulate the impacts on both the
11 Numerical solution of the model is necessitated by the fact that NEG models are only analytically tractable under artificially abstract assumptions concerning the nature of geographic space such as, for example, the "racetrack" economy assumption (Fujita et al., 1999). Such assumptions are incompatible with the operationalization of NEG for applied policy purposes.
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model's short- and long-run equilibrium solutions. Using the short-run solution will
capture the impacts on key economic variables taking the distribution of employment
both across regions and between sectors to be fixed to that under the baseline scenario.
Meanwhile, using the long-run solution will capture the additional impacts associated
with labor mobility and migration. Simulating the long-run equilibrium does, however,
introduce an extra layer of complexity, not least because of the crudeness of the
modelling of migration decisions in NEG theory to date.
4. An illustrative application to China
We illustrate implementation of the model and its use for evaluating possible changes in
regional economies due to transport sector investments with an application to China. We
use a multi-region NEG model to simulate the aggregate and regional economic impacts
of China's National Expressway Network (NEN). This application combines regional
economic accounts data with estimates of minimum road network travel times which
have been derived using GIS techniques for both the baseline and counterfactual
scenarios. Because of data limitations12, in this particular application our “baseline”
corresponds to the situation after implementation of the infrastructure investment
program—i.e., using data for 2007. Our counterfactual is the situation without upgraded
or newly constructed expressways, which was the situation in the early to mid 1990s.
This application is still under development. The description here is primarily intended for
the purposes of methodological illustration, including the demonstration of the types of
12 We have complete data available for a large set of geographic units for 2007, but due to re-aggregation of administrative units over time, these do not match data available for a much smaller set of spatial units for the 1990s.
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results that our approach can be expected to generate. At this point, our application only
makes use of the second part of our methodology. Thus, it makes assumptions about key
parameter values that we intend to estimate in the next phase. Furthermore, at this stage,
we focus only on simulating the short-run impacts of the NEN. Although the results we
report cannot yet be considered reliable estimates of impacts, our application does
demonstrate that a relatively simple two-sector NEG model is able to adequately describe
the spatial distribution of key economic variables across Chinese regions in 2007. This is
despite the complete neglect, at this stage, of alternative forces shaping China's economic
geography. The application also showcases the regional economic accounts and GIS road
network dataset that we have been developing.
4.1. The model
Our model for China extends Krugman's (1991a, 1991b) original model in several
important directions. We retain the two-sector structure of this model with increasing
returns in one of the sectors and constant returns in the other, but generalize it from two
to more than 300 regions. Following Fujita et al. (1999, chapter 7), we furthermore
extend the presence of both transport costs and "love of variety" preferences (and,
therefore, product differentiation) from just the increasing returns sector to both sectors.
This has the benefit of introducing an extra dispersion force into the model, thereby
dampening the well-known agglomeration bias of the original Krugman model (Fujita et
al, 1999, chp. 7). Finally, rather than following the NEG convention of interpreting the
increasing returns sector as "manufacturing" and the constant returns sector as
"agriculture", in line with the discussion in section 1, we instead think of these sectors as
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corresponding to the urban and rural sectors of the Chinese economy. This allows us to
simulate not only the aggregate and regional economic impacts of the NEN, but also its
impacts on urban-rural disparities within individual prefectural level regions.13
4.1.1. Micro-assumptions
More concretely, on the consumption side of the model, the utility function is taken to be
Cobb-Douglas, θθ −= 1RCU , where C denotes the level of consumption of a composite
commodity produced by the urban sector and R the level of consumption of a composite
commodity produced by the rural sector. Both C and R are functions of the separate
varieties of commodities produced within the respective sectors. This is captured by the
use of constant elasticity of substitution (CES) sub-utility functions for C and R:
)1/(
1
/)1()(−
=
−⎥⎦
⎤⎢⎣
⎡= ∑
σσσσ
x
iicC [1]
)1/(
1
/)1()(−
=
−⎥⎦
⎤⎢⎣
⎡= ∑
ηη
ηηy
j
jrR [2]
The quantity of each variety produced by the urban sector is c(i), where i∈{1,…, x} and x
represents the number of varieties. Analogously, the quantity produced of each rural
variety is r(j), where j∈{1,…, y} and y is the number of varieties. σ and η denote the
elasticity of substitution between varieties produced in the urban and rural sectors
respectively, where both σ and η > 1 and, in general, we expect η ≠ σ.
13 So far as we are aware, NEG models have not previously been applied in such a manner.
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The objective of households is to maximize utility subject to their budget constraint.
Given the static nature of the model, income in the budget constraint is equal to the sum
of expenditure on C and R.
Turning to the production side, there is free entry and exit of firms in both sectors, but
only urban sector production is characterized by internal economies of scale. These arise
from the existence of a fixed labor requirement, s, for the production of c(i), where labor
is assumed to constitute the only input and each urban firm produces only one variety.
Thus, )(iacsL += , where a denotes the marginal labor requirement. However, firms in
both sectors incur transport costs when shipping commodities to a region other than that
in which they are located. In particular, the cost of transporting a unit of output from
region k to region r is denoted by CkrT for the urban sector and R
krT for the rural sector.
The profit maximising free on board (f.o.b.) price of the rural sector commodity is equal
to the marginal cost of production. Given the normalization that the marginal labor
requirement in the sector is unity, this implies pR = wR , i.e. that the price is equal to the
nominal rural wage rate. By contrast, the profit maximising f.o.b. price for urban sector
varieties is pC = wCaμ, where wC is the nominal urban wage and μ = σ/(σ - 1) represents
a fixed mark-up on marginal costs.14 Using the additional normalization a = 1/μ then
implies pC = wC. Finally, the price of region k’s output in region r, taking account of the
14 μ is also equal to the ratio of average to marginal costs for urban sector firms. It therefore also provides a measure of the degree of returns to scale in equilibrium.
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cost of transport from k to r (c.i.f.), is given by CCkr wT and RR
kr wT for the urban and rural
sectors respectively.
4.1.2. Reduced Form of the Model in Short-Run Equilibrium
The assumption of free entry and exit of firms in both sectors in response to non-zero
profits combined with the absence of worker mobility both between regions and sectors,
allows for the derivation, for each region k∈{1,…,N}, of five simultaneous non-linear
equations. Taken together, these equations represent the reduced form of the model's
short-run equilibrium:
σ
σσ/1
1
11 )()( ⎥⎦⎤
⎢⎣⎡= ∑
=
−−N
r
Ckr
Crr
Ck TGYw [3]
ηηη
/1
1
11 )()( ⎥⎦
⎤⎢⎣
⎡= ∑
=
−−N
r
Rkr
Rrr
Rk TGYw [4]
)1/(1
1
1)(σ
σλ−
=
−⎥⎦
⎤⎢⎣
⎡= ∑
R
r
Ckr
Crr
Ck TwG [5]
)1/(1
1
1)(η
ηφ−
=
−⎥⎦
⎤⎢⎣
⎡= ∑
N
r
Rkr
Rrr
Rk TwG [6]
Rkk
Ckkk wwY φθθλ )1( −+= [7]
where Ckw and R
kw denote nominal urban and rural wage rates respectively in region k;
CkG and R
kG the respective price indices; and kY the level of nominal income in k. The
terms λr and φr are equal to the respective shares of a region in the national supply of
urban and rural workers. Meanwhile, θ is the preference parameter for the composite
urban sector commodity, which, under utility maximization, is also equal to the share of
22
expenditure on urban output. Following Fujita et al. (1999), we assume that θ is equal to
the national share of urban workers in total employment.
Equation [3] represents the well-known NEG wage equation, according to which wages
in the urban sector are a transport cost discounted function of incomes in all other regions
with which trade takes place. The local price index for urban sector varieties also enters
into this equation because we are concerned here with nominal wages. In most NEG set-
ups, this equation is taken as only applying to the increasing returns sector. However,
equation [4] shows that, in our model, a similar relationship also holds for the rural
sector, which is characterised by constant returns to scale. This is because of the presence
of transport costs in this sector. It is the estimation of equations [3] and [4] that will
correspond to the first stage of our methodology, and which will allow us to obtain
estimates of, in particular, the key parameters σ and η when our application to China is
fully developed. Equations [5] – [7] make clear that both prices and incomes in all
regions within the full structural model are endogenously determined, which reflects the
general equilibrium nature of the model.
4.2. Data, model parameterisation and implementation issues
To apply the model to simulate the impacts of the construction of China's NEN we make
use of a data set for 2007 which covers a sample of 331 prefectural level regions.15 This
data set has been constructed from several different sources published by the National
Bureau of Statistics for China (namely, the Regional Economic, Urban Statistical and
15 Both this data set and the construction of our GIS road networks data are discussed in more detail in the appendix.
23
China Statistical Yearbooks for 2008), with additional data coming from various
provincial statistical yearbooks.16 Included in the data set are measures of both urban
and rural employment.17 Using these measures, we are able to directly calculate the
values of the parameters λr, φr and θ for 2007. The 331 prefectural level regions include
280 prefectural cities (out of a total of 283).18 However, these "cities" are not to be
understood in the traditional sense of the word. Indeed, the definition of a prefectural city
typically covers not only a central urban area (the city proper), but also the, frequently
extensive, rural periphery which surrounds this city.19 Included in this periphery are
smaller urban centres (county-level cities). In addition to the 280 prefectural cities, we
also have Beijing, Tianjin and Shanghai, which, although they are municipalities, we treat
as prefectural level regions. The remainder of the sample consists largely of a mixture of
"Prefectures", "Ethnically Minority Autonomous Prefectures" and "Leagues", which are
even more rural than prefectural cities.20 Overall, our sample accounted for about 93 % of
overall Chinese employment and about 99 % of overall GDP in 2007.21
16 These yearbooks are published by individual provincial statistical bureaus. 17 In our main sources, data is only available on urban employment and total employment. Consequently, we calculate rural employment as total employment minus urban employment. 18 We exclude Tianshui City in Gansu Province and Lhasa City in Tibet on account of a lack of data. Also excluded is Karamay City, which is an oil-producing and refining center located in Xinjiang autonomous region. The performance of this region cannot be explained by NEG-style forces. 19 Reflecting this, on average, 65.4 % of a prefectural city's population was classified as agricultural in 2007. This average is based on the full set of 283 prefectural cities. 20 In addition, the sample includes Shihezi City, a county-level city under the direct jurisdiction of Xinjiang Province, and Chongqing Municipality, which, on account of its size, we have divided into three separate areas which correspond to the so-called "one hour economic circle" and the two "wings." These areas are as defined in the Chongqing Municipal Government's development strategy (“Guidelines on pushing forward the coordinated urban-rural reform and development in Chongqing Municipality”, State Council, Jan 26th, 2009). 21 Previous studies in the empirical NEG literature which have made use of prefecture level region data for China are Au and Henderson (2006a), Bosker et al. (2009) and Hering and Poncet (2008). These studies, however, include only the prefectural cities in their samples. Consequently, their geographical coverage of China is less extensive.
24
In addition to values for λr, φr and θ, implementation requires us to make assumptions
about the functional form for transport costs in both the urban and rural sectors. Whereas
these are ordinarily modelled as functions of straight line distance, we model them as
functions of the minimum estimated road network travel time between regional
population centres. For the rural sector, we maintain the traditional exponential form for
transport costs so that krRtRkr eT τ= , where tkr denotes the estimated travel time between
regions k and r, and assume that τR = 1. This implies that costs increase very sharply
with tkr. By contrast, for the urban sector, we assume a power functional form for
transport costs, Ckr
Ckr AtT τ+= 1 . We assume that A = 1 and τC = 0.82. This implies that the
costs of transporting urban sector output are concave with respect to travel time. Au and
Henderson (2006a) assume a similar functional form in estimating the NEG wage
equation using data on the urban areas of prefectural cities for 1997, except using straight
line distances instead of travel time, and the assumed value of τC is based on this study.
At present, we do not yet model the costs of transporting output within regions. Rather, as
reflected in the assumed transport cost functions, we normalize these costs to unity across
all regions.22
We also require values for σ and η. Eventually, we intend to estimate both of these
parameters by explicitly estimating equations [3] and [4] using an extended version of
our current dataset. For the time being, however, we assume that σ = 3. This value is
based on Au and Henderson (2006a) and Bosker et al. (2009). In particular, Au and
22 As discussed further in section 5, our modelling of transport costs, in particular, their functional form, remains, at this stage, the least developed of our analysis and is one of the major reasons why our application to China currently remains tentative.
25
Henderson (2006a) obtain values of σ ≈ 2 in estimating a version of equation [3], while
Bosker et al. (2009) estimate σ = 3.83 using panel data for 264 prefectural cities covering
the period 1995-2005. With these parameters, the value of η is that which maximizes the
linear correlation between the simulated nominal output series from our baseline scenario
and the actual nominal GDP for 2007.23 The maximum correlation occurs for η = 9.24
This implies substantially more substitutability between rural varieties than assumed for
varieties of urban goods.25 On the whole, this seems plausible.
One final issue is the assumption, implicit so far in our model, that the Chinese economy
is closed to international trade. This assumption means that wages depend only on
domestic market potential in equations [3] and [4]. In light of China's rapid export led
growth over the last three decades, we consider this to be unrealistic, especially for the
urban sector. We follow Au and Henderson (2006a) by adding an international
component to market potential for the urban sector in equation [3]. We model the
strength of this international component for a region k as varying inversely with the costs
of transporting output to and from the nearest city with a major international port. In
particular, we assume 82.01 kportC
kport tT += where kportt is the minimum estimated road
network travel time between k and either Shanghai or Qinhuangdao City (whichever is
less).
23 As measured by the Pearson product moment correlation coefficient for data in our 331 regions. 24 We arrived at η = 9 by conducting a numerical search over values of η in the range 1 < η ≤ 20. The search was restricted to integer values of η. 25 Each region produces its own distinctive exogenously determined fixed measure of rural product varieties, and the value of η designates the constant cross-region elasticity of substitution, with a value of infinity corresponding to completely undifferentiated or homogeneous varieties, and increasingly smaller values indicating increasing differentiation between regions.
26
4.3. Results
4.3.1. Model fit
Before simulating the impacts of the construction of the National Expressway Network,
we can assess how well the baseline (short-run equilibrium) solution of our model, fits
the actual data. From Table 1, there is a very strong positive correlation between the
simulated output levels (SIM Y) for the 331 prefectural level regions and their actual
2007 GDP levels (GDP). A strong correlation also exists between simulated levels of
output per worker (SIM Y PW) and actual GDP per worker (GDP PW), as well as
between simulated levels of output per capita (SIM Y PC) and actual GDP per capita
(GDP PC). Unfortunately, our data set does not include measures of urban and rural
wages, but it does have a variable labeled "Average Wages of Staff and Workers"
(ACTUAL W) and also includes measures of urban disposable income per capita
(URBAN Y PC) and rural household per capita net income (RURAL Y PC). Comparing
ACTUAL W with a weighted average of simulated urban and rural wages (SIM W)26
gives a correlation coefficient of around 0.56, which is similar to the correlations for
simulated urban wages (SIM W-UR) and simulated rural wages (SIM W-RUR) with
URBAN Y PC and RURAL Y PC respectively.
26 The weights we use in constructing SIM W are the respective shares of the urban and rural sectors in a region's employment in 2007.
27
Table 1: Correlation between simulated variables and actual data for 2007
SIM W SIM W-UR
SIM W-RUR SIM Y SIM
Y PW SIM Y PC
ACTUAL W 0.5605 0.2503 0.4208 0.5517 0.5449 0.5893
URBAN Y PC 0.6339 0.5669 0.4369 0.6329 0.6292 0.7250
RURAL Y PC 0.7567 0.5952 0.5803 0.6300 0.7578 0.8082
GDP 0.5834 0.5975 0.4271 0.9268 0.5712 0.5906
GDP PW 0.7224 0.3054 0.5438 0.4625 0.6997 0.6434
GDP PC 0.7212 0.3950 0.5426 0.5160 0.6975 0.7293
Notes: The reported correlation co-efficients are Pearson product moment correlation coefficients. Correlations involving ACTUAL W, GDP, GDP PW and GDP PC are based on the full sample of 331 regions; correlations involving URBAN Y PC and RURAL Y PC are based on 317 regions due to data unavailability for 14 regions
The correlation between SIM W-RUR and RURAL Y PC is also shown in figure 1. From
this, the model appears to substantially over-predict rural wages for 8 prefectural level
regions, which are labelled. At the current stage of model development, we refrain from
attempts to identify the reasons for these outliers.
Figure 1: Scatterplot of actual rural household net income per capita –v– simulated rural wage level
28
Given that the model is able to simulate both urban and rural wages, it can also simulate
urban-rural disparities within regions. Thus, we are able to compare simulated urban-
rural wage ratios with a proxy from our dataset, which is the ratio of urban to rural
income per capita. The mean simulated ratio (3.043) is remarkably similar to the mean
for our proxy from the actual data (2.942). But our model over-predicts the dispersion of
urban-rural wage ratios across regions, as is clear from Figure 2a. Figure 2b also shows
that our model simulates a relatively large number of regions (47) as having 2007 urban-
rural wage ratios which are less than unity. This is when, in reality, the minimum ratio of
actual urban to rural income per capita was 1.66 (for Mudanjiang City, Heilongjiang
Province).
Figure 2(a): Histogram of simulated and actual urban-rural disparities across prefectural level regions; (b) scatterplot of simulated versus actual urban-rural disparities
4.3.2. Changes in estimated travel times from the National Expressway Network
These preliminary results show that our model does a reasonable job in reproducing the
actual geography of some key economic variables in China in 2007, notwithstanding
remaining problems, particularly in predicting rural wages for some regions and in
29
accurately mimicking the distribution of urban-rural disparities. These issues as well as
some other loose ends to the model remain to be resolved before the current application
can be considered concrete.
With this in mind, we now turn to simulating the aggregate and spatial economic impacts
of the building of the NEN. We first compare estimated minimum travel times by road
before and after the introduction of the network. In particular, Figure 3 shows the
distribution of estimated time savings. The distribution is truncated at 0 and,
consequently, is positively skewed. Reflecting this, the mean reduction in travel time is
8.7 hours and the median reduction is 7.7. The standard deviation is 5.9 hours. Plotting
travel time against straight line distance for the 55,615 unique combinations of regions in
our prefectural sample for both before and after gives Figure 4. As this figure illustrates,
the construction of the expressway network has essentially resulted in a parallel shift
downwards in the relationship between travel time and distance. Thus, the new network
has led to a fairly uniform reduction in travel times across the whole of China.27
27 This is confirmed by regressions that show that the estimated slope coefficient of the relationship between travel time and distance is identical to 2 decimal places when comparing before and after. This constant co-efficient is accompanied by a large fall in the estimated intercept.
30
Figure 3: Travel time savings Figure 4: Travel times –v– distance
4.3.3. Estimated aggregate and spatial economic impacts
Efficiency
We can obtain an aggregate estimate of the benefits of building the NEN by calculating
the level of aggregate simulated real income for the Chinese economy associated with
both the baseline and counterfactual solutions of the model. This suggests benefits equal
to 4.5 % of aggregate real simulated income in 2007. These estimated benefits represent a
permanent level effect on overall Chinese real income. It is necessary to calculate the
benefits in real terms because the model implies large impacts of the highway network on
both nominal income levels and prices across regions.28
Equity
Figure 5 shows the distribution of simulated gains/losses in real income, real urban wages
and real rural wages across the 331 prefectural regions, here represented by points at the
28 Aggregate simulated real income is calculated as ]1)()/[(
1θθ −∑
=
RrGC
rGN
r rY .
31
location of their main city. In figure 5(a) we see that, for real income, all regions share in
the benefits. However, these benefits are far from being uniformly distributed. They
range from a minimum of 0.18 % of 2007 real income for Hotan Prefecture in Xinjiang
province to a maximum of 23.5 % for Zhuhai City, which is located in Guangdong
province.
Figure 5: Changes (%) in simulated levels of: (a) real income, (b) real urban wages and (c) real rural wages in the scenario with expressways relative to the counterfactual scenario (without expressways) a.
b. c.
32
At the sectoral level, the picture is more mixed, particularly in the urban sector (figure
5b). Thus, although 86.1 % of regions have higher real urban wages in 2007 than would
have otherwise been the case in the absence of the expressways, for the remainder, real
wages are simulated as being lower than under the counterfactual scenario. In a number
of cases, the simulated losses relative to the counterfactual are substantial. For 14 regions,
the model suggests that real urban wages in 2007 would have been higher by 10 % or
more had the National Expressway Network not been built. For five regions (Taizhou
City, Jiangsu province; Guangan City, Sichuan province; Anshun City, Guizhou
province; Qujing City, Yunna province; and Changji Hui A.P, Xinjiang province) the
gain in real urban wages would have been in excess of 20 %.
Likewise, in the rural sector, 15 regions are simulated as having lower real wages in 2007
in the baseline scenario with expressways than in the counterfactual scenario without
expressways (Figure 5c). In four cases (Ningbo, Zhoushan and Zhuhai cities, Zhejiang
province; and Urumqi City, Xinjiang province), according to the simulation results, real
wages would have been higher by 5 % or more in the counterfactual scenario, and in two
cases (Ningbo City and Urumqi City) they would have been higher by 10 % or more. In
general, the benefits in the urban sector are strongly negatively correlated with those in
the rural sector. Specifically, the Pearson correlation coefficient between the differences
in real urban wages and real rural wages in the two scenarios is equal to –0.796. This
explains why simulated losses in real urban or real rural wages do not translate into
simulated losses in overall real income.
33
Turning to the impacts on urban-rural disparities, 115 regions (37.7 % of the sample) are
simulated as having lower urban-rural wage ratios as a result of the travel time reductions
associated with the NEN, while the remainder have higher ratios than would otherwise be
the case (Figure 6). Despite this, averaging across all regions, the simulated urban-rural
wage ratio is lower under the 2007 scenario, where it is equal to 3.07, than under the
counterfactual (before the investments), where it is equal to 3.15. Consistent with this,
the largest fall in the urban-rural wage ratio is for Guangan City (Sichuan province)
where it is simulated that it would have been 6.11 in the absence of the expressways
rather than 3.35. By contrast, the largest increase in the simulated urban-rural wage ratio
is Luohe City (Hanan province) where it is 4.78 in the baseline compared to 4.10 in the
counterfactual.
Figure 6: Simulated urban-rural disparities in the baseline scenario (with expressways) versus in the counterfactual scenario (without expressways)
5. Summary and the way forward In this paper, we have reported on progress on a research project which is intended to
improve our ability to answer two key policy questions related to large-scale inter-
regional transportation infrastructure projects. First is the efficiency question – what are
34
the aggregate benefits associated with such projects in developing countries? Second is
the spatial equity question – what is the spatial distribution of benefits? In particular, do
such projects primarily benefit lagging regions, thereby promoting their catch-up with
leading regions, as is frequently the intention of policymakers? Or, by heightening the
relative strength of agglomeration forces, do they benefit mainly the leading regions,
possibly even at the expense of the lagging ones?
Our analytical approach is based on the so-called new economic geography. The value-
added of an NEG approach to evaluating benefits relative to standard CBA practices and
the approach adopted in the macro level empirical literature is that the NEG provides for
an explicitly spatial general equilibrium framework, which incorporates both
agglomeration and dispersion forces. It allows moving beyond a consideration of benefits
measured simply as travel time reductions, changes in vehicle operating costs or changes
in traffic related accidents to the potentially wider impacts associated with induced
changes in the spatial distribution of economic activity. Furthermore, within an NEG
framework, these impacts can be linked to a relatively small set of key structural
parameters, which might help to explain the apparently contradictory results for different
types of samples which have been a characteristic feature of the macro level empirical
literature. An NEG-based approach is also ideally suited to addressing the spatial equity
question, including the possibility of trade-offs between efficiency and spatial equity.
More concretely, we have outlined a two-stage methodology for the operationalization of
NEG for the purposes of evaluating the benefits of major inter-regional transportation
35
projects and illustrated key aspects of this methodology with an application to the
construction of China's National Expressway Network. From an operational point of
view, this may be an atypical application. In a project context it is more likely that the
task is to evaluate the impacts of an investment in a specific transport network link rather
than an upgrade of an entire system. The modelling approach proposed in this paper can
obviously be applied in such contexts as well, while still incorporating economy wide
impacts of even very partial improvements.
As emphasized throughout, this application remains in its preliminary stages. We intend
to expand and improve the model in three specific areas. The first question which we
must confront concerns the appropriate modelling of transport costs. The use of estimated
travel times that are explicitly derived using GIS techniques from detailed digital
representations of a country's road network—both prior and following major
investments—is already a major step forward in modelling these costs. But there remains
the question of what is the appropriate functional form which maps these travel times to
transport costs? As emphasized in section 4.2, our current choices of functional form
are somewhat ad hoc, as are the values we choose to parameterize these functional
forms.29
The second task is to explicitly implement the first stage of our methodology. Instead of
assuming values for, in particular, the elasticities of substitution between varieties in the
urban (σ) and rural sectors (η), the goal is to estimate these parameters. This will require 29 A related issue is the estimation of travel times within regions. We can again make use of an extensive GIS database for China to compute summary statistics for intra-prefectural travel times that should better reflect urban-rural linkages in each geographic unit.
36
the estimation of the NEG wage equations (i.e., equations [3] and [4]) associated with
both sectors. Although previous studies have estimated the NEG wage equation using
Chinese regional data and we referred to the most relevant of these studies to select our
assumed value for σ in section 4.2, no study to date has estimated the wage equation for
China's rural sector. Furthermore, estimating the wage equations will also provide us with
an opportunity to empirically investigate non-NEG influences on regional economic
outcomes in China. These include, for example, the importance of first-nature geography
(i.e. natural endowments) and the role of human capital. What we learn about these forces
will then be fed back into the development of our model.30
Finally, thus far, we have only simulated the impacts of the construction of China's NEN
associated with the short-run equilibrium of the NEG model we have been developing.
However, to complete the application, we also intend to simulate the outcomes associated
with the model's long-run equilibrium. This will allow us to capture the additional effects
associated with the migration of labor both between regions and between sectors.
30 As should be clear from examining the structural equations [3] – [7] in our model, estimating these equations will involve tackling difficult issues of endogeneity, for instance with respect to project placement. This is because, with an NEG approach, the key determinants of a region's market potential are endogenously determined.
37
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40
Appendix
Data sources and data integration
A1. Economic data
Original sources
The main original sources for our prefectural level dataset are the Regional Economic
Statistical Yearbook 2008 (RESY 2008), the Urban Statistical Yearbook 2008 (USY 2008)
and the China Statistical Yearbook 2008 (CSY 2008) published by the National Bureau of
Statistics of China, as well as relevant provincial statistical yearbooks published by the
respective provincial statistics bureaus. With data from these sources, we construct a
dataset of 331 entities for analysis at the prefectural level of China.
Prefectural regions in China
Under the central government, the hierarchy of the administrative divisions of China is
made up of four tiers of regional units: the provincial level, the prefectural level, the
county level and the township level. The province is the basic unit of the country’s
territory, similar to the state in the United States, although with much less autonomy.
Also at the provincial level are the municipality and the autonomous region. Below the
provinces are the prefectural level units. By the end of 2007, there were 333 prefectural
level regions in China, of which 283 were ‘Prefectural Cities’ (CSY 2008).
Because it usually has a significant rural component, a prefectural city is quite different
from a traditionally defined city. A typical prefectural city consists of three kinds of units
that are considered counties. The first is called 'District under Cities', and all the districts
41
together form the 'City Proper' (Shiqu in Chinese) of the prefecture, which mostly
consists of urban areas, and the political and economic centre of the whole prefecture.
The second is called 'County', which, with its own urban centre, covers most of the rural
areas of the prefectural city. The third is called 'County-level City', which was once a
county and then renamed as a 'city' due to its increased urbanization level. For the 283
prefectural cities, on average by 2007 65.4% of a prefectural city’s population is
registered as agricultural population, while around 80% of the population of counties and
county-level cities under a prefectural city is registered as agricultural population; 15.5%
of the GDP of a prefectural city is from the primary sector, while for counties and
county-level cities under it the percentage is 23.2% (USY 2008).31
The other prefecture-level regions include ‘Prefectures’, ‘Ethnic Minority Autonomous
Prefectures (A.P)’ and ‘Leagues’, of which the last two kinds are dominated by ethnic
minority populations. These regions are even less urbanized than prefectural cities. A
prefecture can become a prefectural-level city after meeting certain criteria.32 Although
not included in the 333 prefectural regions, ‘Districts’ under municipalities are also at the
prefectural level administratively.33
31 Of the 283 prefectural cities, 13 do not have any counties or county-level cities and are thus excluded in the respective calculation. 32 Non-agricultural population of the county-level cities under the prefecture must be over 150, 000 (120, 000 if the population density is under 50 persons/ kilometre2); non-agricultural population of the prefectural council’s location must be over 120,000 (100, 000 if the population density is under 50 persons/ kilometre2); the total GDP must be over 2.5 billion RMB with the tertiary industry’s share over 30% ; the total fiscal revenue must be over 150 million RMB. Source: Ministry of Civil Affairs. 33 Notice that the ‘District’ under a prefectural city and the ‘District’ under a municipality are at different administrative levels
42
To get the widest coverage possible, our dataset includes all 283 prefectural cities, with
the exceptions of Tianshui City in Gansu Province and Lhasa City in Tibet due to missing
data. For the same reason, the 6 prefectures in Tibet are also excluded, while all the other
prefectures, autonomous prefectures and leagues are included. We also follow Hering and
Poncet (2008) and Bosker et al. (2009) by including three municipalities, Beijing, Tianjin
and Shanghai, as 3 single entities alongside the prefectural units. Although these
municipalities are administratively at the provincial level, they resemble some large
prefectural cities, both in terms of population and territory size, except that they are much
more urbanized. Unlike Hering and Poncet (2008), we divide Chongqing Municipality
into three regions as its population and territory size, not to mention its urbanization rate,
are closer to a small province.34 Shihezi City, a county-level city under the direct
jurisdiction of Xinjiang Province, also enters the dataset. Finally, we drop Karamay City
in China’s remote western region, whose economic structure is heavily biased by
dominance of the oil production and refining industry.
As a result, there are 331 entities in our sample. Overall, they account for 86.2% of
China’s land area, 96.2% of its population, 93 % of its total employed population and
99% of its GDP. Relevant previous studies down to the prefecture level of China (Au
and Henderson, 2006a, 2006b; Hering and Poncet, 2008; Bosker et al., 2009) have only
focused on the prefectural cities. Comparatively, our sample thus has larger coverage.
34 The division is based on Chongqing’s ‘One Circle, Two Wings’ regional development strategy that divides the municipality into the ‘One Hour Economic Circle’, ‘Northeast Wing’ and ‘Southeast Wing’. Actually it is most of the ‘two wings’ that had been added to the jurisdiction of Chongqing in 1997 as it was separated from Sichuan Province and upgraded to a municipality. The corresponding data is thus collected from the Chongqing Statistical Yearbook 2008 instead of RESY 2008.
43
Construction of the main variables
Based on the simplest version of Fujita et al. (1999), our model has a two-sector structure
with an increasing returns sector and a constant returns sector. According to the typical
urban-rural dual economic structure of prefectural regions discussed above, we identify
the increasing returns sector and constant returns sector with a prefectural region’s urban
areas and rural areas respectively.
Following this urban-rural dichotomy, we construct the main variables that are used to
solve the 5 simultaneous non-linear equations in our model. To get the value of shares of
a region in the total supply of C- and M-sector workers (φ and λ respectively) that are
assumed to be exogenous in the short-run, we use the statistics of Urban Employed
Persons (UEP) and Total Employed Persons (TEP), which are available from RESY
2008.35 We then calculate the Rural Employed Persons (REP) as the residual of TEP
minus UEP.36 With the data of UEP and REP, we calculate the value of φ and λ for each
prefectural unit for the year 2007. We also get the share of a prefecture's total
employment which is in the constant returns sector (SHARE C) and the share of which is
in the increasing returns sector (SHARE M), which can be use to calculate the simulated
combined wage.
35 Employed Persons refer to persons aged 16 and over who are engaged in gainful employment and thus receive remuneration payment or earn business income. This indicator reflects the actual utilization of the labour force during a certain period of time (CSY 2008). 36 Without direct data on Rural Employed Persons at the prefecture level, our treatment can be justified by the fact that, according to various provincial statistical yearbooks, the numbers of urban employed persons and rural employmed persons exactly sum to the number of total employed persons at the provincial level.
44
To calibrate the model, we maximize the correlation between simulated income and
actual GDP to select the value of the elasticity of substitution parameter for the rural
sector before comparing simulated values of the model’s key endogenous variables with
their actual observable counterparts to assess model “fit”. With respect to the actual wage
rate, we construct three variables. The only directly present statistics reflecting actual
wages is the Average Wages of Staff and Workers (ACTUAL W) from RESY 2008,
although the concept of Staff and Workers37 does not completely correspond to that of
Employed Persons that is used to get the simulated wage. Therefore, we also use the data
of TEP and population as well as GDP for each prefecture to calculate the GDP per
worker (GDP PW) and GDP Per Capita (GDP PC) for each prefectural unit.
There are two categories of directly available data that reflect the income level of urban
areas and rural areas for each prefectural unit from RESY 2008, which are Urban
Household Disposable Income (URBAN Y PC)38 and Rural Household Per Capita Income
(RURAL Y PC)39 respectively.
37 Average Wage refers to the average wage in money terms per person during a certain period of time for staff and workers in enterprises, institutions, and government agencies, which reflects the general level of wage income during a certain period of time and is calculated as follows:
Time Referenceat Workers and Staff ofNumber Average
Time Referenceat Workers and Staff of Bill WageTotal
WageAverage =
Staff and Workers refer to persons who work in, and receive payment from, units of state ownership, collective ownership, joint ownership, share holding ownership, foreign ownership, and ownership by entrepreneurs from Hong Kong, Macao, and Taiwan, and other types of ownership and their affiliated units. They do not include 1) persons employed in township enterprises, 2) persons employed in private enterprises, 3) urban self-employed persons, 4) retirees, 5) re-employed retirees, 6) teachers in the schools run by the local people, 7) foreigners and persons from Hong Kong, Macao and Taiwan who work in urban units, and 8) other persons not to be included by relevant regulations. (CSY 2008) 38 Disposable Income of Urban Households refers to the actual income at the disposal of members of the households which can be used for final consumption, other non-compulsory expenditure and savings. This is equal to total income minus income tax, personal contributions to social security and subsidies for keeping diaries in being a sample household. The following formula is used:
45
Table A 1: Summary statistics for the key variables40
N Minimum Maximum Mean Std. Deviation
Φ 331 .00 .01 .0030 .0022
λ 331 .00 .03 .0030 .0037
SHARE C 331 .01 .93 .6889 .1778
SHARE M 331 .07 .99 .3111 .1778
ACTUAL W 331 9658.0 49310.0 21072.8 5444.2
GDP 331 10.1 12188.9 837.7 1241.9
GDP PW 331 6133.0 226829.0 36857.6 27599.7
GDP PC 331 3405.0 98398.0 20214.4 15476.1
URBAN Y PC 317 5873.0 33593.0 12231.2 3581.5
RURAL Y PC 331 1232.0 11606.0 4410.6 1833.2
Valid N (listwise) 316
Disposable income = total household income - income tax - personal contribution to social security - subsidy for keeping diaries for a sampled household 39 Net Income of Rural Households refers to the total income of rural households from all sources minus all corresponding expenses. The formula for calculation is as follows: Net income = total income - household operation expenses - taxes and fees - depreciation of fixed assets for production - subsidy for participating in household survey - gifts to non-rural relatives (CSY 2008) 40 Karamay City is the prefectural city with both the highest levels of GDP per capita and per worker, despite being located in Xinjiang autonomous region (i.e. about as far in China's interior as possible). This performance is attributable to its status as an oil-producing & refining region (http://en.wikipedia.org/wiki/Karamay).
46
A2. Transport cost estimates We employ a spatially explicit model of transport infrastructure by using geographic
information systems (GIS) data of the Chinese road network. Georeferenced road
information for China is from the Australian Consortium for the Asian Spatial
Information and Analysis Network (ACASIAN; www.asian.gu.edu.au). The base
network consists of 20,899 line segments with attribute information indicating the type of
road represented by each link. After including the expressway network, the complete
database has 31,538 segments. Figures A1 and A2 show the network without and with
expressways.41
Standard spatial analysis techniques allow us to determine the most likely route through
the network that will connect each prefecture with each of the remaining 330 prefectural
units. Our measure of transport cost is network travel time. While road upgrading might
not significantly change distances between two urban centers, it typically reduces travel
times. For each road type we determined a suitable travel speed (design speed) ranging
from 10 km/h for unpaved city streets to 75 km/h for expressways (Table 1).42 Given the
GIS calculated real world length of each segment, we compute the time required to
traverse each road link which is the basis for computing the fastest inter-prefecture
network routes.
41 See also World Bank (2007). 42 These speed estimates were determined by transport sector specialists working in the East Asia region.
47
Table A2: Road types and assumed feasible travel speed
Road type Pavement type
Assumed speed (km/h)
City street paved 10 Local road unpaved 10 paved 15 Motorway unpaved 20 paved 30 National highway unpaved 35 paved 50 Provincial highway unpaved 35 paved 50 Expressway paved 75
We compute the fastest routes through the network between each prefecture pair using a
standard shortest-path (Dijkstra) algorithm, where in this application, rather than
distance, travel time is minimized. This involves identification of 54,615 travel times for
the base network and for the complete network. A simple initial measure of the
importance of each road network link is the number of times each link is used. Figures
A3 and A4 show the resulting maps for the network without and with expressways. The
major network arteries in the eastern regions of China appear prominently in these maps.
48
Figure A 1: Road network before the expansion of the National Expressway Network
Figure A 2: Road network with expressways
49
Figure A 3: Importance of network links (before NEN)
Figure A 4: Importance of network links (full network with highways)