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Cross-country Convergence and Growth:
Evidence from Nonparametric and Semiparametric Analysis
Kui-Wai Li a,* and Xianbo Zhoub a City University of Hong Kong, Hong Kong
b Lingnan College, Sun Yat-Sen University, China
Paper submitted to
APEC Study Center Consortium Conference
September 22 – 23, 2011
San Francisco, USA
2
Cross-country Convergence and Growth:
Evidence from Nonparametric and Semiparametric Analysis
Kui-Wai Li a,* and Xianbo Zhoub a City University of Hong Kong, Hong Kong
b Lingnan College, Sun Yat-Sen University, China
Abstract
This article studies the absolute and conditional convergence of real GDP per capita
among 164 world economies over the sample period of 1970-2006. The data-driven
model specification tests justify the use of nonparametric and semiparametric models.
The estimation results show that control variables play a negative/positive channel effect
in the growth convergence for poor/developed economies. The absolute convergence
hypothesis tends to hold only for the economies with low development levels, but the
conditional convergence hypothesis tends to hold for all the economies.
Keywords: convergence, nonparametric, semiparametric, growth
JEL Classifications: C14, F43, O11, O40
____
* Corresponding author: Kui-Wai Li, Department of Economics and Finance, City University of Hong Kong. Tel.: +852 3442 8805; Fax: +852 3442 0195; E-mail: [email protected]
3
I Introduction
In the growth and development literature, parametric regression analysis has
empirically been used to test the convergence hypothesis that poorer economies will
catch up with wealthier economies (Baumol, 1986; Barro and Sala-i-Martin, 1992; Islam,
1995; Evans and Kim, 2005). Much of the empirical research has concentrated on
whether per capita income growth converges once structural differences across
economies have been controlled for. In the parametric regression, a negative parametric
estimate of the coefficient on the initial income is interpreted as evidence of convergence.
Different parametric methodologies based on exogenous and endogenous growth models
have been employed in studying income convergence. Some studies conducted panel unit
root test on the convergence hypothesis (Quah, 1994; Levin and Lin, 1993; Im et al.,
1997). Others used the system-generalized method of moments for the dynamic panel
data model (Bond et al. 2001) to show that earlier results might be seriously biased due to
weakness of the instruments in the first-differenced generalized method of moments
approach. The convergence debate is summarized and analyzed in Islam (2003).
A key assumption in the conventional studies with parametric models is that
cross-country growth is linear with identical rate of convergence across countries and the
convergence is only tested according to the parametric estimate of the coefficient on the
initial income. However, as some new growth theories (Azariadis and Drazen, 1990;
Durlauf and Johnson, 1995) have shown, cross-country growth can be non-linear and is
characterized by multiple steady states and the implied rates of convergence differ
between different groups of economies.
In contrast to the above parametric studies, nonparametric approaches that
pre-specify neither the income distribution form nor the functional form of the regression
4
function have been applied to the study of convergence. For example, Bianchi (1997)
studied the convergence hypotheses among 119 countries by means of bootstrap
multimodality tests and nonparametric density estimation techniques and supports the
clustering and stratification of growth patterns over time. Wang (2004) applied a
nonparametric approach to test the convergence hypothesis of the income distribution
across the 59 provinces and states in the U.S. and Canada and finds club convergence or
multi-modality of the per capita income over the sample period. Lauruni et al. (2005)
employed nonparametric methodology to analyze the evolution of relative per capita
income distribution of Brazilian municipalities over the period 1970-1996. In a more
recent literature, Juessen (2009) used nonparametric estimation to study GDP
convergence in the labor market across different regions in Germany for the period
1992-2004, and the bimodality result indicated sizeable disparities between regions.
Although nonparametric estimation relaxes the assumption on the same rate of
convergence across countries, these nonparametric analyses have excluded other steady
state growth determinants and have concentrated on the empirical research of the absolute
convergence.
To control for structural differences across countries in the steady state, recent
empirical research used semiparametric methods to test the conditional convergence
hypothesis and estimated the implied rate of convergence as a function of the initial
income. Kumer and Ullah (2000) developed a local linear instrumental variable method
with a kernel weight function to estimate the smooth varying coefficient function and
applied it to estimate the speed of convergence of a panel of cross-countries per capita
output. Dobson et al. (2003) presented a brief semiparametric analysis on the
cross-country convergence by simply pooling the data for 103 countries covering the
5
period 1960-1990 and provided evidence for nonlinear convergence. Azomahou et al.
(2011) applied a semiparametric partially linear model to approximate the relationship
between the growth and initial GDP per capita across European regions and confirmed
the nonlinearity in the convergence process.
The growing popularity of nonparametric and semiparametric approaches stems
from their ability to relax functional form assumptions in regression model and let the
data determine the convergence process (Henderson et al., 2008). The nonlinearity and
the heterogeneity in structural economies can be accounted for since there is little prior
knowledge on a particular convergence process. A more general data-based specification
of the functional form is robust to the functional misspecification for convergence.
Therefore, nonparametric and semiparametric models can be more flexible than
parametric models in describing the nonlinearity in the convergence process and the
multiple steady states in the economy.
In light of the nonlinearity in the convergence process and the heterogeneity of
cross-country structural economies, this article proposes the use of both nonparametric
and semiparametric panel data models to study absolute and conditional convergence,
respectively. By using an unbalanced panel data set of 164 world economies over the
period 1970-2006, this article examines whether differences in macroeconomic and
institutional factors, endowments, and other country characteristics have played a role in
per capita income growth and convergence among world economies. As we know, panel
data analysis on the income convergence can incorporate heterogeneity across economies.
The fixed and random effects are often specified in the growth model for the
unobservable heterogeneity in the economies. There is no agreement as to which kind of
6
effects is more suitable to enter into the model1. However, in order to obtain consistent
estimates for the nonparametric function of the lagged output and the speed of
convergence, no matter whether the individual effect is random or fixed, we apply the
fixed-effects specification in our nonparametric and semiparametric models, as suggested
by Henderson et al. (2008).
Section II describes the data and variables. Section III presents the estimation of the
nonparametric and semiparametric models and the model specification tests with
unbalanced panel data. Section VI reports empirical estimation and analysis. Section V
presents the testing results which justify the semiparametric and nonparametric model
specification. Section V concludes the paper.
II Data and Selection of Variables
We include in the convergence models a total of nine control variables in the vector
of characteristics in order to reflect differences in the steady state equilibrium and to
capture a variety of socio-economic factors. These nine variables are: investment
(investment share of real GDP per capita), inflation (annual percentage of GDP deflator),
government size (government expenditure share of real GDP per capita), trade
(percentage share of trade in GDP), foreign direct investment (percentage share of net
foreign direct investment in GDP), life expectancy, urbanization (share of urban people in
total population), private credit share (domestic credit to private sector as a percentage of
1 When the individual effect is independent of the regressors, the estimation of both the random-effects
model and the fixed-effects model is consistent with each other, except that the random effects estimator is
more efficient. However, when the individual effect is correlated with any of the regressors, the random
effects estimator is biased and inconsistent whereas the fixed effects estimator still leads to consistent
estimates and is appropriate for the estimation of regression functions.
7
GDP), and carbon dioxide emission (carbon dioxide emission per capita).
The data for the real GDP per capita (gdpc) are in 2005 constant prices derived from
growth rates of consumption, government expenditure and investment. We include
investment (ki) as a control variable since it has been one of the determinants in the
conventional Solow growth model. The rate of inflation (deflator) acts as a proxy for
macroeconomic stability with the intention to test the hypothesis of the negative effect to
income growth found in several studies (Fischer, 1993; Barro, 1995). Government size
(kg) is used to proxy an institutional indicator and to test if a larger government size was
likely to harm growth, as shown in Iradian (2003, 2005). Trade openness (trade) and
foreign direct investment (fdi) are included in our analysis as trade has always been seen
as an important catalyst for economic growth and foreign direct investments generate
increasing returns in production through positive externalities and spillover effects
(Frankel and Romer, 1999; Dollar and Kraay, 2001; Makki and Somwaru, 2004). Health
in the form of life expectancy (life) has appeared in many cross-country growth
regressions and has been generally found to have a significant positive effect on the rate
of economic growth (Bloom and Canning, 2000; Bloom et al., 2001). Life expectancy is
thus used to indicate whether increased expenditures on health are justified on the
grounds of their impact on economic growth. Urbanization (urban) has been viewed
necessary for achieving high growth, high income, increased productivity and efficiency
through specialization, diffusion of knowledge, size and scale (Annez and Buckley, 2009;
Duranton, 2009; Quigley, 2009). However, urbanization may also deter firms from
locating in larger cities due to negative spillovers including congestion and high land
rents, leading to dampening effect on economic growth. Urbanization is included in our
analysis to provide evidence if its progress supports income growth. The remaining two
8
variables of carbon dioxide emission (co2) and private credit share (credit) are used to
capture the environmental issue and level of financial development, respectively.
The data are sourced from the Penn World Tables, World Development Indicators
and the United Nations. The unbalanced panel dataset (see Appendix) used in the analysis
contains 4,450 observations on 164 world economies for the period 1970-2006, with each
country containing at least two-year data to fit in with our nonparametric estimation.
III Nonparametric Models and Specification Test
Recent empirical studies using the semiparametric approach have challenged
parametric specifications that stemmed from the linearity in the convergence process.
This article re-examines the convergence process by specifying nonparametrc and
semiparametric panel data models. Nonparametric method relaxes the assumption of the
identical speed of convergence implied in parametric models and allows convergence to
be related to the initial economic development level. The generated flexibility allows the
data of the economies to determine the functional form of the initial income. We will also
present model specification tests which show that our models are justified in studying the
convergence process.
The nonparametric panel data model with country-specific fixed effects is specified
as
, 1 , 1ln( ) ln( ) (ln( )) ,it i t i t i itgdpc gdpc g gdpc u v− −− = + + (1)
where 1,2, , ; 1,2, , ,it m i n= =L L ln( )itgdpc is the logarithm of real GDP per capita
and the functional form of ( )g ⋅ is not specified and , 1ln( ) ln( )it i tgdpc gdpc −− is the
growth rate of real GDP per capita. Each country i has im observations. For consistent
9
estimation of ( )g ⋅ , we specify a nonparametric estimation of the fixed effects model,
that is, the individual effects iu are fixed effects which are allowed to be correlated with
, 1ln( )i tgdpc − . The error term itv is assumed to be i.i.d. with a zero mean and a finite
variance, and is mean-independent of , 1ln( )i tgdpc − , namely , 1( | ln( )) 0it i tE v gdpc − = .
The semiparametric panel data model with country-specific fixed effects is the
semiparametric counterpart of Model (1) with control variables. It is specified as
', 1 , 1ln( ) ln( ) (ln( )) ,it i t i t it i itgdpc gdpc g gdpc x u vβ− −− = + + + (2)
where itx is the vector of the logarithms of control variables accounting for differences
in investment, economic environment including rate of inflation, trade openness and
intensity of foreign direct investment, degree of financial market development indicated
by private credit share, as well as social and human indicators including government
consumption share, life expectancy, carbon dioxide emission and urbanization. The
assumptions of the error term itv are similar to those in Model (1), and that they are i.i.d.
with a zero mean and a finite variance, and is mean-independent of , 1ln( )i tgdpc − ,
namely , 1( | ln( )) 0it i tE v gdpc − = . The regression function ( )g ⋅ of Model (2) and the
derivative of ( )g ⋅ are the focus in our estimation. If ( )g ⋅ has a known function form
with unknown parameters, Models (1) and (2) become parametric models, with the
former used to study absolute convergence and the latter used to study conditional
convergence.
It follows from the neoclassical growth model that the growth rate is inversely
correlated to the distance from the steady-state value. According to Rassekh (1998), the
speed of convergence λ can be expressed as
10
*ln( ) ln( ) ln( ) .itit
d gdpc gdpc gdpcdt
γ ⎡ ⎤= −⎣ ⎦
The rate is inversely correlated with the distance between the actual GDP per capita
ln( )itgdpc and the final value *ln( )gdpc in steady state. If the convergence rate is
assumed to be a constant, we can write the convergence model in a stochastic form as
*, 1 , 1ln( ) ln( ) (1 ) ln( ) (1 ) ln( )it i t i t i itgdpc gdpc e gdpc e gdpc u vλ λ− −− −− = − − + − + + ,
denoted as *
, 1 , 1ln( ) ln( ) ln( ) ln( ) ,it i t i t i itgdpc gdpc gdpc gdpc u vβ β− −− = − + +
where *gdpc is the income level at the steady state which can be determined by other
control variables of the economy, andβ is the derivative of the growth rate with respect
to , 1ln( )i tgdpc − and can be estimated by regression. Then the speed of convergenceλ
can be calculated by
ln(1 ).λ β= − + (3)
Correspondingly, for Model (1) and Model (2), we replaceβ in (3) by the derivative
function of the growth rate with respect to , 1ln( )i tgdpc − and define the speed of
convergence λ as a function of ln( )gdpc :
(ln( )) ln(1 '(ln( ))),gdpc g gdpcλ = − + (4)
where '( )g ⋅ is the first derivative function of ( )g ⋅ . Therefore, λ is interpreted as the
convergence rate of the economy to the steady-state and this speed may be different in
different initial development level in the economy.
Nonparametric model (1) and semiparametric model (2) can be estimated by the
iterative procedures modified for the unbalanced panel data models in Henderson et al.
(2008). We use the same notation as those in Henderson et al. (2008) to illustrate our
11
model specification in unbalanced panel data. Denote , 1ln( ) ln( )it it i ty gdpc gdpc −= −
and ln( )it itz gdpc= . To remove the fixed effects in Model (1), we write:
1 1 1 1( ) ( ) ( ) ( )it it t it i it i it i ity y y g z g z v v g z g z v≡ − = − + − ≡ − +% % .
Denote 2( , , ) 'ii i imy y y=% % %L , 2( , , ) '
ii i imv v v=% % %L and 2( , , ) 'ii i img g g= L , where
( )it itg g z= . The variance-covariance matrix of iv% and its inverse are calculated as
2 '1 1 1( )
i i ii v m m mI e eσ − − −Σ = + and 1 2 '1 1 1( / )
i i ii v m m m iI e e mσ− −− − −Σ = − , where 1imI − is an
identity matrix of dimension 1im − and 1ime − is a ( 1) 1im − × vector of ones. The
criterion function is given by:
11 1 1 1 1
1( , ) ( ) ' ( ), 1,2, ,2i i ii i i i i m i i i i mg g y g g e y g g e i n−
− −Ξ = − − + Σ − + =% % L .
Denote the first derivatives of 1( , )i i ig gΞ with respect to itg as , 1( , )i tg i ig gΞ ,
1,2, it m= L . Then
' 1,1 1 1 1 1
' 1, 1 , 1 1 1
( , ) ( ),
( , ) ( ), 2,i i
i
i g i i m i i i i m
i tg i i i t i i i i m
g g e y g g e
g g c y g g e t
−− −
−− −
Ξ = − Σ − +
Ξ = Σ − + ≥
%
%
where , 1i tc − is an ( 1) 1im − × matrix with ( 1)t − th element/other elements being 1/0.
Denote ( )0 1( , ) ' ( ), ( ) / 'g z dg z dzα α ≡ . It can be estimated by solving the first order
conditions of the above criterion function iteratively:
( ), [ 1] 1 0 1 [ 1]1 1
1 ˆ ˆ( ) ( ), , ( , ) ', , ( ) 0i
i tg i
mn
h it it l i it l imi ti
K z z G g z G g zm
α α− −= =
− Ξ =∑ ∑ L L ,
where the argument ,i tg
Ξ is [ 1]ˆ ( )l isg z− for s t≠ and 0 1( , ) 'itG α α when s t= , and
[ 1]ˆ ( )l isg z− is the ( 1)l − th iterative estimates of 0 1( , ) 'α α . Here itG ≡ ( )1,( ) / 'itz z h−
12
and 1( ) ( / )hk v h k v h−= , ( )k ⋅ is the kernel function. The next iterative estimator of
0 1( , ) 'α α is equal to ( )[ ] [ ]ˆ ˆ( ), ( ) 'l lg z g z = 11 2 3( )D D D− + , where:
' 1 ' ' 1 '1 1 1 1 1 1 , 1 , 1
1 2
' 1 ' 12 1 1 1 1 [ 1] 1 , 1 , 1 [ 1]
1 2
3
1 ( ) ( ) ,
1 ˆ ˆ( ) ( ) ( ) ( ) ,
1
i
i i
i
i i
mn
m i m h i i i i t i i t h it it iti ti
mn
m i m h i i l i i t i i t h it it l iti ti
i
D e e K z z G G c c K z z G Gm
D e e K z z G g z c c K z z G g zm
Dm
− −− − − −
= =
− −− − − − − −
= =
⎛ ⎞= Σ − + Σ −⎜ ⎟
⎝ ⎠⎛ ⎞
= Σ − + Σ −⎜ ⎟⎝ ⎠
=
∑ ∑
∑ ∑
' 1 ' 11 1 1 ,[ 1] , 1 ,[ 1]
1 2
( ) ( ) ,i
i
mn
h i i m i i l h it it i t i i li t
K z z G e H K z z G c H− −− − − −
= =
⎛ ⎞− − Σ + − Σ⎜ ⎟⎝ ⎠
∑ ∑
and ,[ 1]i lH − is an ( 1) 1im − × vector with elements:
( )[ 1] [ 1] 1ˆ ˆ( ( ) ( )) , 2, ,it l it l i iy g z g z t m− −− − =% L .
The series method can be used to obtain an initial estimator for ( )g ⋅ . The convergence
criterion for the iteration is set to be:
( )2 2[ ] [ 1] [ 1]
1 2 1 2
1 1ˆ ˆ ˆ( ) ( ) / ( ) 0.01.i im mn n
l it l it l iti t i ti i
g z g z g zm m− −
= = = =
− <∑ ∑ ∑ ∑
Further, the variance 2vσ is estimated by
2ˆvσ = 21 1
1 2
1 1 ˆ ˆ( ( ( ) ( )))2 1
imn
it i it ii ti
y y g z g zn m= =
− − −−∑ ∑ .
The variance of the iterative estimator ˆ ( )g z is calculated as 1ˆ( ( ))nh zκ −Ω , where
2 ( )k v dvκ = ∫ , and 2
1 2
11ˆ ˆ( ) ( ) /imn
ih it v
i ti
mz K z zn m
σ= =
−Ω = −∑ ∑ .
For the estimation of semiparametric Model (2), we denote the nonparametric
estimator of the regression functions of the dependent variable y and the control
variables x as ˆ ( )yg ⋅ and ˆ ( )xg ⋅ = ,1ˆ( ( ), ,xg ⋅ L ,ˆ ( )) 'x dg ⋅ , where d is the number of
13
controls. Then β is estimated by
β̂ =1
' 1 ' 1* * * *
1 1/ /
n n
i i i i i i i ii i
x x m x y m−
− −
= =
⎛ ⎞ ⎛ ⎞Σ Σ⎜ ⎟ ⎜ ⎟
⎝ ⎠ ⎝ ⎠∑ ∑% % % % ,
where *iy% and *ix% are, respectively, ( 1) 1im − × and ( 1)im d− × matrices with the
t th row element being
*it ity y= −% % ˆ( ( )y itg z 1ˆ ( ))y ig z− and * ˆ( ( )it it x itx x g z= − −% % 1ˆ ( ))x ig z .
The nonparametric function ( )g ⋅ is estimated by the same method as above except that
ity% is replaced by ' ˆit ity x β−% whenever it occurs.
To incorporate a data-driven procedure for model selection, we further modify the
specification tests for unbalanced panel data. The first specification test is to choose in
Model (1) between parametric and nonparametric models, that is whether absolute
convergence should be estimated by parametric or nonparametric models. The null
hypothesis H0 is parametric model with 0( ) ( , )g z g z γ= while the alternative H1 refers
( )g z as nonparametric. The test statistics for testing this null is
(1) 20
1 1
1 1 ˆ ˆ( ( , ) ( ))imn
n it iti ti
I g z g zn m
γ= =
= −∑ ∑ ,
where γ̂ is a consistent estimator of the parametric model with fixed effects; ˆ ( )g ⋅ is
the iterative consistent estimator of Model (1).
The second specification test is to choose in Model (2) between parametric and
semiparametric models, that is whether conditional convergence should be estimated by
parametric or semiparametric models with control variables. The null hypothesis H0 is
parametric model with 0( ) ( , )g z zθ γ= . The alternative is that ( )g z is nonparametric.
The test statistic for testing this null is
14
(2) ' ' 20
1 1
1 1 ˆˆ( ( , ) ( ) )imn
n it it it iti ti
I g g x g z xn m
γ β β= =
= + − −∑ ∑ %% ,
where γ% and β% are consistent estimators in the parametric panel data model; ˆ ( )g ⋅
and β̂ are the iterative consistent estimator of Model (2).
For the empirical study, we apply bootstrap procedures in Henderson et al. (2008) to
approximate the finite sample null distribution of test statistics and obtain the bootstrap
probability values for the test statistics.
IV Empirical Results
For comparison with the semiparametric Model (2), we also present parametric
estimation results for the conditional convergence model. Table 1 reports the empirical
results of Model (2) in its parametric version, estimated by three parametric approaches
of Pooled OLS, Fixed Effects and System-Generalized Methods of Moments (GMM).
The semiparametric estimation results for the control variables by the nonparametric
iterative approach of Section III are listed in the last column of Table 1. In addition to the
conventional linear specification, we further estimate the conditional convergence model
with ( )g ⋅ being a quadratic polynomial of , 1ln( )i tgdpc − in Model (2) to test whether
the speed of convergence is related to initial development.
15
Table 1 Parametric estimation results for conditional convergence models Parametric model Semiparametric
model Pooled OLS Fixed effects System-GMM gdpc -0.0126* 0.0091 -0.0704* -0.1525* -0.0251** -0.0026 ---
(0.0025) (0.0174) (0.0073) (0.0504) (0.0114) (0.0664) --- gdpc2 --- -0.0012 --- 0.0048*** --- -0.0011 ---
--- (0.0010) --- (0.0028) --- (0.0038) --- Ki 0.0185*** 0.0181*** 0.0174 0.0183 0.0459** 0.0436** 0.0259*
(0.0104) (0.0105) (0.0231) (0.0230) (0.0184) (0.0202) (0.0064) Kg -0.0105* -0.0106* -0.0421* -0.0402* -0.0226** -0.0174*** -0.0421*
(0.0025) (0.0025) (0.0092) (0.0094) (0.0103) (0.0095) (0.0049) urban -0.0009 -0.0013 -0.0014 -0.0024 -0.0083 -0.0003 -0.0052
(0.0031) (0.0031) (0.0111) (0.0113) (0.0134) (0.0146) (0.0073) co2 0.0048* 0.0047* 0.0176* 0.0188* 0.0043 0.0050 0.0331*
(0.0016) (0.0016) (0.0048) (0.0050) (0.0047) (0.0066) (0.0034) deflator -0.0185* -0.0187* -0.0224* -0.0225* -0.0182* -0.0189* -0.0216*
(0.0029) (0.0029) (0.0039) (0.0039) (0.0055) (0.0054) (0.0022) trade 0.0032 0.0028 0.0328* 0.0325* 0.0159** 0.0151 0.0299*
(0.0020) (0.0020) (0.0072) (0.0072) (0.0078) (0.0100) (0.0044) life 0.0525* 0.0500* 0.0069 0.0082 0.0818*** 0.0544 0.0303***
(0.0129) (0.0128) (0.0243) (0.0242) (0.0439) (0.0421) (0.0162) credit -0.0047** -0.0045** -0.0016 -0.0024 -0.0090 -0.0096 -0.0079*
(0.0019) (0.0019) (0.0040) (0.0039) (0.0055) (0.0059) (0.0026) Fdi 0.0357*** 0.0373*** 0.0282 0.0260 0.0666*** 0.0600 0.0011
(0.0197) (0.0200) (0.0245) (0.0239) (0.0388) (0.0402) (0.0107) Notes: The dependent variable is , 1ln( ) ln( )it i tgdpc gdpc −− . The numbers in the parentheses except in the last column are standard errors of the coefficient estimates. The numbers in the parentheses in the last column are bootstrapping standard errors. Estimates of the intercepts in parametric models are not reported. *, ** and *** indicate significance at 1%, 5%, and 10% levels, respectively. λ is the implied rate of convergence, which is calculated by (3) in the models with a linear function of gdpc and as ln( ( ) 1)gdp barβ −− + in the models with a quadratic function of gdpc, gdp bar− is the sample average of log(gdpc). The two system-GMM estimations are two-step robust. Second order correlation statistics and difference-Sargen p-values of the two system-GMM estimation show valid use of instrumental variables.
The performance of system-GMM estimator can be evaluated by establishing a
bound for the autoregressive parameter. The OLS estimator and the within-groups (fixed
effects) estimator are used to establish an upper and a lower bound, respectively, for the
estimated coefficient of the initial income term. This would mean that a consistent
16
estimate of the initial income term coefficient can be expected to lie in between the OLS
levels and within-groups estimates (Bond et al., 2001). The results shown in Table 1
support the system-GMM estimation, with the two estimates lying within those in the
OLS upper and within-groups lower bound.
The conventional linear specification of the conditional convergence model
estimated by system-GMM estimation (column 5) shows a significant negative
coefficient on the initial income term (-0.0251), while the quadratic specification (column
6) gives an insignificant coefficient estimation. The more reliable linear conditional
convergence model gives an average convergence rate of 2.5 percent (column 5) with
positive estimates on coefficients of the five control variables (investment, carbon
dioxide, trade openness, life expectancy and foreign direct investment), reflecting
differences in the steady-state equilibrium. In particular, life expectancy (8.18%) has the
greatest positive and significant effect. This agrees with the empirical evidence that
health plays an important role in determining economic growth rates (Bloom and
Canning, 2000; Bloom et al., 2001). Other variables carry different levels of impact to
economic growth – ranging from foreign direct investment (6.66%), investment share
(4.59%), trade openness (1.59%), and to carbon dioxide emission (0.43%).
On the contrary, government consumption, urbanization, inflation and private credit
share produce a negative impact to economic growth. The significant negative figures for
government size (-0.0226) and inflation (-0.0182) support the fact that inefficient
government expenditure and high inflation rates would hinder economic growth (Iradian,
2003, 2005; Fischer, 1993; Barro, 1995). On the whole, the linear specification of the
conditional convergence model estimated by the system-GMM method gives positive
estimates on investment, carbon dioxide emission, trade, life expectancy and foreign
17
direct investment, but negative values for other economic growth determinants
(government size, urbanization, inflation, and private credit share).
In our nonparametric and semiparametric estimation of Model (1) and Model (2),
the kernel is the Gaussian function and the bandwidth is chosen according to the rule of
thumb: 1/ 51.06 ( )h stdc z N −= × × , where ( )stdc z is the standard deviation of z , the
logarithm of the initial GDP per capita in the sample and N is the sample size. Both the
standard errors for the coefficient estimates in the parametric part of Model (2) and the
lower and upper bounds of 95 percent confidence intervals of the estimate ˆ ( )g ⋅ in the
nonparametric part of Model (2) are calculated by the bootstrap approach. The model
specification test statistics and the probability values for the tests are calculated by the
approach proposed in Henderson et al. (2008). All the bootstrap replications are set to be
400.
Column 7 in Table 1 shows that the coefficients estimates of the control variables in
the semiparametric conditional convergence Model (2) are identical in direction to those
in the parametric model estimated by system-GMM (in columns 5 and 6). Investment,
carbon dioxide emission, trade, life expectancy and foreign direct investment contribute
positively to economic growth while government size, urbanization, inflation, and private
credit share exert negative effects.
Table 2 shows the estimation of the nonparametric function and the implied speed of
convergence at some quartile points of the logarithm of initial real GDP per capita by
using both nonparametric Model (1) and semiparametric Model (2). It can be seen that
the estimates of ( )g ⋅ from semiparametric Model (2) are smaller than those from
nonparametric Model (1) at all the quartile points of ln(gdpc). This shows that the
18
estimates of ( )g ⋅ become smaller after the conditional variables are controlled for,
suggesting that the control variables play an important role in pushing up the values of
ˆ ( )g ⋅ at the initial development level when nonparametric Model (1) is estimated.
Therefore, when the steady state is controlled for, the net contribution of initial
development to the growth will be smaller than the gross contribution of initial
development to the growth when the steady state is not controlled for. This suggests that
the indirect contribution of initial income to growth via the control variables is an
important part in the gross contribution of initial income to economic growth.
Table 2 Estimation of the Nonparametric Function ( )g ⋅ at some points of ln(gdpc)
Quartile of ln(gdpc): z Nonparametric Model (1) Semiparametric Model (2)
g(z) speed λ g(z) speed λ 2.5% 6.6906 0.0132 0.0103 0.0017 0.0171 25% 7.6004 0.0149 -0.0042 -0.0481 0.0096 50% 8.5355 0.0191 -0.0025 -0.0980 0.0092 75% 9.4387 0.0211 -0.0006 -0.1491 0.0114 95% 10.2365 0.0187 0.0003 -0.1828 0.0081
97.5% 10.3700 0.0163 0.0037 -0.1908 0.0127 mean of ln(gdpc): 9.2365 0.0190 -0.0024 -0.0978 0.0092
Table 2 also shows that the estimates of the convergence speed λ (calculated by
(4)) at the quartiles and the mean of ln(gdpc) estimated from Model (2) are larger than
those estimated from Model (1). This further affirms the contribution of the control
variables or the steady state of economies to growth and its convergence process.
Contrary to the positive role which control variables play in the gross contribution of
initial income to growth, the role of the control variables in the gross contribution of
initial income to the convergence speed is negative. That is, the total effect of control
19
variables on growth is positive whereas the total effect of control variables on
convergence speed is negative.
Figure 1 illustrates the estimation of nonparametric function ( )g ⋅ in Models (1)
and (2) with the lower and upper bounds of 95 percent confidence intervals. The
nonparametric estimates are acceptable, though with some boundary effects when initial
income level is extremely high. The shapes of the two curves of ( )g ⋅ look very similar
at very low level of initial income, but very different from an initial income level of
around 6.6 (around $735). Both curves take a downward slope when the initial income
level is below $735. However, for an income level above $735, the curve estimated by
the nonparametric model takes a flat shape around zero values while the curve estimated
by semiparametric model keeps on sloping downwards to more negative values. When
the control variables are controlled for, a higher initial development level tends to result
in lower growth. This gives the marginal effect of initial development on growth.
Figure 1 Estimation of Nonparametric Function ( )g ⋅ in Model (1) and Model (2)
20
Our finding is consistent with the neoclassical prediction that poor countries would
grow faster than rich countries if the only difference is their initial levels of capital (Swan,
1956). The higher the income level is, the larger the role played by the control variables
in changing the nonlinear shape of ( )g ⋅ . Since the growth is calculated by statistics in
which the effects of control variables are contained, it is mainly related to our
nonparametric estimation of ( )g ⋅ in Model (1). Therefore, our finding is also consistent
with the reality of growth, especially in developed economies, in the long run that growth
in developed countries would generally be low or close to zero. Figure 1 provides an
adaptive description on this prediction.
Figure 1 can be stated in a different way. The contribution by the steady state or
control variables to economic growth can be seen from the vertical distance between the
two curves estimated by nonparametric and semiparametric models. At income levels
below $735, the vertical distance decreases as income levels increases. The opposite
occurs for income levels above $735 – the vertical distance increases as income level
increases. The vertical distance can be explained as the channel effect of initial
development on economic growth via the control variables. Whenever the estimates of
( )g ⋅ by semiparametric model are larger than those by nonparametric model, the
channel effect is negative, but becomes positive when the opposite occurs. The control
variables as a whole cannot contribute to economic growth explained by the initial
development at or below the low income level of around $735. In some sense, they have
a dampening effect on ( )g ⋅ .
On the other hand, when the income level is above $735, the indirect or channel
effect becomes positive. This implies that the control variables as a channel tend to
21
increase economic growth at higher stage of income level. This evidence shows that
whether the control variables will have positive contribution to economic growth
explained by initial development level depends on the income levels of economies. Our
finding shows that control variables have played a negative channel effect in the growth
convergence for poor economies while they played a positive channel effect in the
convergence for developed economies. Figure 1 suggests that the absolute convergence
hypothesis tends to hold only for the economies with low per capita GDP levels (<$735).
However, the conditional convergence hypothesis tends to hold for all the economies.
Figure 2 gives a comparison of the implied speeds of convergence calculated from
the nonparametric and semiparametric regression models. Since the control variables are
used as proxies for the steady state for conditional convergence, the speed of conditional
convergence calculated from the semiparametric estimation of Model (2) has controlled
for the effects from the steady state. However, the nonparametric Model (1) has
suppressed the contribution of the control variables in the gross effect of initial income on
growth for the unconditional convergence, and hence the speed of absolute convergence
calculated from the nonparametric estimation of Model (1) has embodied the effect from
the steady state. One can see from Figure 2 that the conditional speed of convergence is
larger than the absolute counterpart at all levels of initial income. This shows that the
inclusion of the control variables in the model decreases the calculated values of the
convergence speed. This finding is essentially identical to that from Table 2. The role of
the control variables in the gross contribution of initial income to the convergence speed
is negative.
22
Figure 2 Comparing the convergence speeds calculated from Models (1) and (2)
Figure 2 also shows that both absolute and conditional convergence speeds are
decreasing with the initial development for income levels less than around 6.6 ($735)
with a steep negative slope of an average rate of around 7.3 percent. As the income levels
get higher, the two convergence rates drop. The conditional convergence speed keeps at a
steady rate of around 1.2 percent while the absolute convergence speed keeps at a rate
close to zero until a very high income level of around 10.2 ($26,903) is reached. Such a
high income level raises the absolute convergence speed to a local maximum of 1.5
percent and the conditional convergence speed to a local maximum of 2.1 percent. After
the local maximum speeds, however, the high portion of income levels show a further
decreasing trend for both convergence speeds. Figure 2 confirms the results from Figure
1: the absolute convergence hypothesis tends to hold only for the economies with low per
capita GDP levels with the speed ranging from 0.15 percent to 9 percent and tends not to
hold for most of the economies with per capita GDP greater than $735, whereas the
23
conditional convergence hypothesis holds for almost all the economies with the speed
ranging from 0.15 percent to 14 percent. The economies tend to converge more quickly to
their own steady state than to their common one.
V Model Specification Test
The above analysis rests on our selection of nonparametric and semiparametric
models. Now we apply the test statistics introduced in Section III to justify our model
specification. The parametric model (1) is tested against Model (1) and the parametric
model (2) is tested against Model (2). Table 3 conducts the specification tests for the two
null hypotheses against absolute convergence Model (1) and conditional convergence
Model (2), respectively. All the p-values of the statistics nI are very small, meaning that
we should reject all the nulls for the tests. Thus, the final selection for absolute
convergence model is the nonparametric Model (1) while the final selection for
conditional model is the semiparametric Model (2). These results justify our model
specification for the absolute and conditional convergence models and the corresponding
analysis above.
Table 3 Model specification tests Model Hypotheses In ( p-value) Model selected
Absolute convergence model
Parametric or Nonparametric ?
H0: Linear parametric H1: Nonparametric
5.2409 (0.0000)
Nonparametric
H0: Quadratic parametric H1: Nonparametric
6.4364 (0.0000)
Nonparametric
Conditional convergence model
Parametric or Semiparametric ?
H0: Linear parametric H1: Semiparametric
2.8638 (0.0025)
Semiparametric
H0: Quadratic parametric H1: Semiparametric
2.8937 (0.0000)
Semiparametric
24
VI Conclusion
The multiple steady states in the cross-country growth for the world economy
confirm that there is nonlinearity and non-constant implied rates of convergence between
different groups of economies in the convergence process. This article investigates the
absolute and conditional convergence of real GDP per capita among 164 world
economies over the period 1970-2006 by using the estimation of nonparametric and
semiparametric unbalanced panel data models with fixed effects.
Our econometric estimations on growth convergence can be evaluated with
reference to a number of parametric empirical studies that have chosen similar variables
in their analysis of the conditional convergence issue. However, the data-driven model
specification tests justify the use of nonparametric and semiparametric models to study
absolute and conditional convergence processes instead of the conventional parametric
counterparts. The semiparametric results show that the proxy variables of the steady state
such as investment, carbon dioxide emission, trade, life expectancy and foreign direct
investment contribute positively to economic growth while the other determinants such as
government size, urbanization, inflation, and private credit share exert negative effects.
The comparison between nonparametric and semiparametric results shows that the
indirect contribution of initial income to growth via the control variables is an important
part in the gross contribution of initial income to economic growth. The total effect of
control variables on growth is positive whereas the total effect on the convergence speed
is negative. Control variables play a negative channel effect in the growth convergence
for poor economies, but a positive channel effect in the convergence for developed
economies. The absolute convergence hypothesis tends to hold only for the economies
25
with low per capita GDP levels (<$735). However, the conditional convergence
hypothesis tends to hold for all the economies.
Both absolute and conditional convergence speeds are decreasing with the initial
development for income levels less than around 6.6 ($735) with a steep negative slope of
an average rate of around 7.3 percent. The conditional convergence speed keeps at a
steady rate of around 1.2 percent while the absolute convergence speed keeps at a rate
close to zero until a very high income level of around 10.2 ($26,903) is reached. The
economies tend to converge more quickly to their own steady state than to their common
one. The absolute convergence hypothesis tends to hold only for the economies with low
per capita GDP levels with the speed ranging from 0.15 percent to 9 percent and tends
not to hold for most of the economies with per capita GDP greater than $735, whereas the
conditional convergence hypothesis holds for almost all the economies with the speed
ranging from 0.15 percent to 14 percent.
26
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Appendix: List of sample economies. Albania, 1994-2006. Algeria, 1970-2006. Angola, 1995-2006. Argentina, 1977-2006. Armenia, 1993-2006. Australia, 1970-2006. Austria, 1970-2006. Azerbaijan, 1993-2006. Bahamas, The, 1977-2006. Bahrain, 1981-2005. Bangladesh, 1983-2006. Barbados, 1970-2002. Belarus, 1994-2006. Belgium, 1975-2006. Belize, 1980-2006. Benin, 1970-2006. Bhutan, 1990, 91, 95-2006. Bolivia, 1970-2006. Bosnia And Herzegovina, 1997-2006. Botswana, 1974-2006. Brazil, 1970-2006. Brunei, 2001-2006. Bulgaria, 1991-2006. Burkina Faso, 1970-2006. Burundi, 1970-2006. Cambodia, 1994-2006. Cameroon, 1970-2006. Canada, 1970-2006. Cape Verde, 1987-2006. Central African Republic, 1970-2006. Chad, 1970-2006. Chile, 1970-2006. China, 1979-2006. Colombia, 1970-2006. Comoros, 1982-2006. Congo, (Democratic Republic Of), 1970-95, 2001-2006. Congo, Republic Of, 1970-2006. Costa Rica, 1970-2006. Cote D'Ivoire, 1970-2006. Croatia, 1993-2006. Cyprus, 1980-2006. Czech Republic, 1993-2006. Denmark, 1975-2006. Djibouti, 1992-2006. Dominican Republic, 1970-2006. Ecuador, 1970-2006. Egypt, 1970-2006. El Salvador, 1970-2006. Equatorial Guinea, 1987-1996. Eritrea, 1996-2006. Estonia, 1992-94, 2001-2006. Ethiopia, 1982-2006. Fiji, 1970-2006. Finland, 1975-2006. France, 1975-2006. Gabon, 1970-2006. Gambia, The, 1970-2006. Georgia, 1995-2006. Germany, 1991-2006. Ghana, 1970-2006. Greece, 1976-2006. Guatemala, 1977-2006. Guinea, 1991-2005. Guinea-Bissau, 1986-2006. Guyana, 1970-2006. Haiti, 1991-2006. Honduras, 1970-2006. Hong Kong, 1998-2006. Hungary, 1982-2006. Iceland, 1976-2006. India, 1970-2006. Indonesia, 1980-2006. Iran, Islamic Rep. Of, 1970-2006. Ireland, 1974-2006. Israel, 1970-2006. Italy, 1970-2006. Jamaica, 1970-1997. Japan, 1977-2006. Jordan, 1976-2006. Kazakhstan, 1993-2006. Kenya, 1970-2006. Korea, South, 1976-99, 2001-2006. Kuwait, 1975-89, 95-2006. Kyrgyz Republic, 1995-2006. Laos, 1989-2006. Latvia, 1993-2006. Lebanon, 1989-2006. Liberia, 1974-86, 97-2005. Libya, 2000-2006. Lithuania, 1993-2006. Luxembourg, 2002-2006. Macau, 2002-2006. Macedonia, 1993-2006. Madagascar, 1970-2006. Malawi, 1970-73, 77-2006. Malaysia, 1970-2006. Maldives, 1996-2006. Mali, 1971-2006. Malta, 1971-2006. Mauritania, 1970-2003. Mauritius, 1981-2006. Mexico, 1970-2006. Moldova, 1992-2006. Mongolia, 1991-2006. Morocco, 1970-85, 90-2006. Mozambique, 1988-2006. Namibia, 1990-2006. Nepal, 1972-91, 96-2006. Netherlands, 1970-2006. New Zealand, 1972-2006. Nicaragua, 1970-79, 83-2006. Niger, 1970-2005. Nigeria, 1970-73, 77-2006. Norway, 1975-2003. Oman, 1974-2006. Pakistan, 1970-2006. Panama, 1980-2006. Papua New Guinea, 1973-2006. Paraguay, 1970-2006. Peru, 1970-2006. Philippines, 1970-2006. Poland, 1991-2006. Portugal, 1975-2006. Romania, 1996-2006. Russia, 1993-2006. Rwanda, 1970-2005. Samoa, 1994-2006. Saudi Arabia, 1971-2006. Senegal, 1970-2006. Sierra Leone, 1970-2006. Singapore, 2001-2006. Slovak Republic, 1993-2006. Slovenia, 1992-2006. Solomon Islands, 1981-2006. South Africa, 1970-2006. Spain, 1975-2006. Sri Lanka, 1970-2006. St. Lucia, 1981-2006. St. Vincent And The Grenadines, 1978-2006. Sudan, 1970-2006. Suriname, 1977-2005. Swaziland, 1973-2006. Sweden, 1970-2006. Switzerland, 1983-2006. Syria, 1977-2006. Tajikistan, 1998-2006. Tanzania, 1990-2006. Thailand, 1970-2006. Togo, 1974-2006. Tonga, 1984-2006. Trinidad And Tobago, 1975-2006. Tunisia, 1970-2006. Turkey, 1970-2006. Turkmenistan, 1993-2001. Uganda, 1985-86, 92-2006. United Kingdom, 1970-2006. United States, 1970-2006. Uruguay, 1970-2006. Vanuatu, 1970-2006. Venezuela, 1970-2006. Vietnam, 1992-2006. Yemen, 1991-2003. Zambia, 1970-2006. Zimbabwe, 1979-2005.