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Spatial data analysis, multiregional modeling and macroeconomic growth by Attila Varga Center for Research in Economic Policy (GKK) and Department of Economics University of Pécs, Hungary. Introduction. A -spatial mainstream growth theory
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Spatial data analysis, multiregional modeling and macroeconomic growth by Attila Varga Center for Research in Economic Policy (GKK) and Department of Economics University of Pécs, Hungary
Introduction • A-spatial mainstream growth theory • K, L and A only? How about their spatial arrangements? • Why should we care about space? - Transport cost (evident, but can be integrated) - Spatial externalities (requires a different approach) • Policy relevance (EU)
Outline • Introduction • Technological progress, spatial structure and macroeconomic growth – An empirical modeling framework • Geographical growth studies - methodological issues: • Dependence in space: Spatial data analysis in knowledge spillover research • Spatial macro modeling: Integrating macro and regional levels • Endogenizing spatial structure • Summary
Technological progress, spatial structure and macroeconomic growth Complex issue treated in three separate fields of economics: A. EG: “Endogenous economic growth” models: endogenized technological change in growth theory (Romer 1986, 1990, Lucas 1986, Aghion and Howitt 1998) in Romer (1990): • for-profit private R&D • knowledge spillovers and growth • rate of technical change equals rate of per-capita growth on the steady state • Simplistic explanation of technological progress, no geography
Technological progress, spatial structure and macroeconomic growth B. IS: „Systems of innovation”literature: innovation is an interactive process among actors of the system (Lundval 1992, Nelson 1993) actors of the IS: - innovating firms - suppliers, buyers - industrial research laboratories - public (university) research institutes - business services - “institutions” level of innovation depends on: - the knowledge accumulated in the system - the interactions (knowledge flows) among the actors - codified, non-codified (tacit) knowledge and the potential significance of spatial proximity - does not say anything about geography and growth
Technological progress, spatial structure and macroeconomic growth C. NEG: “New economic geography”models: endogenized spatial economic structure in a general equilibrium model (Krugman 1991, Fujita, Krugman andVenables 1999, Fujita andThisse 2002) - spatially extended Dixit-Stiglitz framework - increasing returns, monopolistic competition - spatial structure depends on some parameter conditions that determine the equilibrium level of centrifugal and centripetal forces - „cumulative causation” - C-P model by Krugman: still the point of departure - models quickly become complex: simulations if analytical solutions are not accessible - Technological change not explained (not even included until very recently), the study of its relation to growth is a recent phenomenon
Technological progress, spatial structure and macroeconomic growth • Theoretical integration: endogenous growth and new economic geography (Baldwin and Forslid 2000, Fujita and Thisse 2002, Baldwin et al. 2003) • EG, IS, NEG: methodological problems in THEORETICAL integration (dramatically diverging initial assumptions, different theoretical structures, research methodologies) • EMPIRICALintegration: very few work (Ciccone and Hall 1996, Varga and Schalk 2004, Acs and Varga 2004)
Technological progress, spatial structure and macroeconomic growth: an empirical modeling framework • Starting points: • Technological change is a collective process that depends on accumulated knowledge and interactions (IS) • Technological change is the simple most important determinant of economic growth (EG) • Codified and tacit knowledge: different channels of spillovers (the „geography of innovation” literature) • Centripetal and centrifugal forces shape geographical structure via cumulative processes (NEG) • The resulting geographic structure is a determinant of the rate of growth (NEG)
Technological progress, spatial structure and macroeconomic growth: an empirical modeling framework • Y = AKαLβ(EG) • The Romer (1990) equation as in Jones (1995) dA = HAAφ, - HA: the number of researchers(“person-embodied”, codifiable/tacit knowledge component of knowledge production) - A: the total stock of technological knowledge (codified knowledge component of knowledge production) - dA: the change in technological knowledge - : the “research productivity parameter”(0<<1) φ: “codified knowledge spillovers parameter” - reflects spillovers with unlimited spatial accessibility : the “research spillovers parameter” - reflects localized knowledge spillover effects - regional and urban economics and the new economic geography suggest: increases with geographic concentration of economic activities
Technological progress, spatial structure and macroeconomic growth: an empirical modeling framework Eq.1 Regional knowledge production Kr = K (RDr, URDr, Zr) Eq.2 Agglomeration effect – RD spillovers ∂Kr/∂RDr = f (RDr, URDr, Zr) Eq.3 R&D location dRDr = R(∂Kr/∂RDr) Eq.4 Geography and = (GSTR(HA)) Eq.5 dA = HAγ Aφ Eq.6 dy/y = H(dA, ZN)
Empirical research on geography, technology and growth: 1986-2004 1986-2004: 253 papers on the geography of knowledge spillovers journal articles: 175 books, book chapters, working papers: 78
Geographical growth studies - methodological issues I. Dependence in space: Spatial data analysis in knowledge spillover research II. Spatial macro modeling: Integrating macro and regional levels III. Endogenizing spatial structure
I. Dependence in space: Spatial data analysis in knowledge spillover research The spatial distribution of US innovations, 1982
I. Dependence in space: Spatial data analysis in knowledge spillover research • Tendency of innovation to cluster in space • Clustering is a consequence of dependence among spatial units • Spatial dependence makes traditional econometric techniques no longer appropriate (Anselin 1988, 2001) • Spatial data analysis: • Exploratory spatial data analysis (ESDA) • Spatial econometrics
I. Dependence in space: Spatial data analysis in knowledge spillover research • ESDA: global and local measures of spatial dependence • Global measures – general form: G = Si,j wij cij • Local measures: • Moran Scatterplot • Local Moran
I. Dependence in space: Spatial data analysis in knowledge spillover research • Spatial econometrics: models with high intuitive value to study spatial knowledge spillovers • Basis: innovation equation in a form of a classical linear regression: y = Xb + e where: y: innovation output; x inputs to innovation • Modeling geographical spillovers – two main issues (Anselin 2003): A. their spatial extent (local or global) B. direct or indirect modeling
I. Dependence in space: Spatial data analysis in knowledge spillover research • Modeling the spatial extent of spillovers: A.1. global autocorrelation modelling e = lWe + u = [I - lW]-1 u A.2. local autocorrelation modelling e = [I + gW] u
I. Dependence in space: Spatial data analysis in knowledge spillover research • Direct or indirect modelling – the most commonly used solutions: B.1. Direct modelling (the „spatial lag model”): y= (I - rW)-1 Xb + (I-lW)-1 u = rWy + Xb + u B.2. Indirect modelling (the „spatial error model”) y= Xb + (I-lW)-1 u
The facts: spatial econometrics in empirical innovation research
Spatial econometrics: Facts, needs and opportunities • Urgent need for extending the toolbox: spatial logit, probit, Tobit, Poisson, panel • User-friendly softwares with support • New intermediate level textbook with applications
II. Spatial macro modeling: Integrating macro and regional levels • Q: how to integrate eqs (1) to (3) (regional level) with eqs (5) and (6) by eq (7) empirically? • An example: the EcoRET model (Schalk and Varga 2004, Varga and Schalk 2004)
EcoRET: The main characteristics • macroEconometric model with Regionally Endogenized Technological change • General features (cost minimization; vintage capital production function; technology and labor/capital demand, output; goods markets; final demand) • Geography and technology development: the conceptual basis - New economic geography - Endogenizing technological change in “endogenous economic growth” models (Romer 1986, 1990, Lucas 1986, Aghion and Howitt 1998) - The geography of knowledge spillovers (Jaffe, Trajtenberg and Henderson 1993, Audretsch and Feldman 1996, Anselin, Varga and Acs 1997)
EcoRET: The modeling framework • Structure of EcoRET – four blocks: • The supply side block (labor market, production, productivity, investment, employment and unemployment, production costs, inflation) • The demand side block (behavioral relationship of private households, consumption, and other components of final demand (government consumption, foreign trade etc.) in real and nominal terms and their deflators) • The income distribution block (determining private and government income - labor and property income, profits - and the transfers of income between private households and the government - taxes, social security and other transfers) • The Total Factor Productivity (TFP) block (modeling changes in regional level TFP as a function of certain knowledge-related variables as well as CSF measures such as promotion of physical infrastructure and human capital) EcoRET consists of: 106 variables, 32 of them are explained by behavioral or technical relationships, 16 variables are exogenous while the remainder of the endogenous variables is explained by definitional identities
EcoRET: Data and estimation • Various Hungarian (Hungarian Central Statistical Office, Hungarian Patent Office) and international (OECD, IMF) data sources • For the period of 1990 - 2000 • Units of observation: - country (macromodel) - counties (technology model) • Parameters - estimation/calibration (macromodel) - pooled estimation (technology model)
EcoRET: The regional TFP block The estimated regional model of technological change TFPGR = α0 + α1KNAT + α2RD+ α3KIMP + α4INFRAINV + α5HUMCAPINV + ε, TFPGR: the annual rate of growth of Total Factor Productivity (TFP), KNAT: domestically available technological knowledge accessible with no geographical restrictions (measured by stock of patents), RD: private and public regional R&D, KIMP: imported technologies (measured by FDI), INFRAINV: investment in physical infrastructure, HUMCAPINV: investment in human capital, region i and time t α1 estimates domestic knowledge spillover effects α2 estimates localized (regional) knowledge spillover effects α3 estimates international knowledge spillover effects
EcoRET: Linking the TFP block to the rest of EcoRET in policy simulations • Problem: - Macro blocks: time series estimation - TFP block: time-space data • Literature: agglomeration and technological change (Feldman 1994, Fujita and Thisse 2002, Varga 2000) • Solution: weighted averaged county TFP growth rates (Excellent historical forecast of national level TFP!) • The linkage: TFP = TFP-1eeDNTFPGR
EcoRET: Simulated effect of the geography of CSF support on the national growth rate • The ratios of the growth effects of concentrating CSF resources in: • leading areas (LEAD/LAG) • lagging areas (LAG/EQUAL) • equal distribution (LEAD/EQUAL)
III. Endogenizing spatial structure • Q: How to endogenize and integrate: equation (3), the R&D location equation, i.e., the long run spatial effects? • A promising solution is to integrate Spatial Computable Equilibrium (SCGE) models (to endogenize R&D distribution) with macroeconometric models to simulate the macroeconomic growth effects.
Summary • An empirical modeling framework is presented • Methodological reasons for a relative negligence of the spatial aspects of macroeconomic growth are reviewed: • Challenges in spatial data analysis • Difficulties in integrating regional and macro levels • Complications in endogenizing spatial structure in empirical macroeconomic growth models