An empirical analysis of the interlinkages between financial sector and economic growth.
Pirtea, Gabriel Marilen ; Dima, Bogdan ; Milos, Laura Raisa 等
1. INTRODUCTION
We consider that one of the most significant transmission channel
between finance and growth is represented by the cost of borrowed
financial resources. Financing costs are an important determinant in
firms' decisions to undertake investment projects. Higher interest
rates, for example, reduce the profitability of an investment project
because of higher financing costs. Therefore, lower the probability of
the project being undertaken.
Having access to a wider and diversified range of financial
resources, the companies can realize their investment projects, adding
value to their company and leading to economic growth. Therefore, in
this paper the authors aim at finding new evidence of the mechanism
through which the economic growth can be achieved. Section 2 reviews a
part of the relevant literature concerning this problem. Section 3
provides the analytical framework. Section 4 offers the empirical
framework. The last section is dedicated to some conclusions and
suggestions regarding potential further research.
2. LITERATURE REVIEW
Levine (1991) is among the first authors that propose models of
endogenous growth that identify the mechanisms through which the
financial system influence the long-run growth of an economy. Le
vine's innovation was to consider financial services as affecting
economic growth through five main channels: savings mobilization,
resource allocation, risk management, managerial monitoring, trade
facilitation. By considering the functions of the financial sector in a
comprehensive manner, Levine is able to demonstrate a significant role
for financial markets that was not present in earlier models that used a
narrower definition. Also, he states that industries and firms that rely
on external financing tend to grow faster in countries with well
developed financial systems than countries with poorly functioning
financial systems.
The positive association between the degree of development of the
financial system and economical growth was largely analyzed also by
Demirguc-Kunt (2006) and Levine and King (1993). They get to the
conclusion that this correlation stays significant even when other
factors of influence are taken into consideration. Moreover, they prove
that regarding a country with a developing financial system, the degree
of financial development is correlated not only with the current growth,
but also with the future economical growth. Their model identifies the
innovation (including the financial one) as engine for economic growth.
The financial markets have the role of discriminate between different
investment projects according to their efficiency potential. In this
way, it is assured the function of efficient allocation. This is the
main reason why, an economy with an efficient financial system will
experiment a higher rate of productivity (Demetriades and Hussein,
1996). These show that, on the case of some countries like Zair or
Mexico, if the volume of loans as percent of GDP would have increased,
respectively the value traded on the capital markets as percent of GDP
would have increased in the considered period of time, then the economic
growth, measured as GDP per capita, would have increased as well.
If the nature of financing the economic growth manner is a key
variable for the economic growth, there are still some important
methodological issues concerning the evaluation of the financing cost.
Thus, the purpose of our study is to take into account the different
components of the borrowed financial resources, in order to examine at
the level of the European Union countries, their impact on the economic
growth.
3. THE ANALYTICAL FRAMEWORK
The analytical framework is represented by a Two-Stage Least Square
(TSLS) regression between the dynamic of real GDP and the relevant
explanatory variables with the inclusion of some cross-section random
effects and also of some period specific instrumental variables. This
could be seen as an appropriate technique when some of the right-hand
side variables are correlated with the error terms, and there is neither
heteroskedasticity, nor contemporaneous correlation in the residuals.
The general specification of the regression model looks like:
[y.sub.it] = [alpha]+[X.sub.it][[beta].sub.t] + [[delta].sub.i] +
[[gamma].sub.t] + [[epsilon].sub.it] (1)
where y is the dynamic of real GDP, [MATHEMATICAL EXPRESSION NOT
REPRODUCIBLE IN ASCII] is the vector of explanatory variables
(divrepresents the dividend yield for each country, obtained as a ratio
between the distributed dividends by the companies that compose the main
index, if possible and the market capitalization, mm the 3-month money
market rate for each country and bm the yield on current 10 years
Government bonds, for each country) with [[beta].sub.t] coefficients
that are period specific, [alpha] is an overall constant, while the
[[delta].sub.i], [[gamma].sub.t] represent cross-section or period
specific effects.
The random effects specifications assume that the corresponding
effects [[delta].sub.i] and [[gamma].sub.l] are realizations of
independent random variables with mean zero and finite variance. Most
importantly, the random effects specification assumes that the effect is
uncorrected with the idiosyncratic residual.
The estimation of the covariance matrix for the composite error
formed by the effects and the residual (e.g., [v.sub.it] =
[[delta].sub.i] + [[gamma].sub.l] + [[epsilon].sub.it] in the two-way
random effects specification), uses the quadratic unbiased estimators
(QUE) from Swamy-Arora method. This estimator uses residuals from the
within (fixed effect) and between (means) regressions. The list of
instrumental variables includes the lagged values of the dependent and
explanatory ones:
[INSTRUMENT.sub.t] = [[gdp.sub.t-1] [div.sub.t-1] [mm.sub.t-1]
[bm.sub.t-1]] (2)
The structure of the correlations between residuals is described as
a Period Heteroskedasticity and Serial Correlation (Period SUR) one.
This class of covariance structures allows for arbitrary period serial
correlation and period heteroskedasticity between the residuals for a
given crosssection, but restricts residuals in different cross-sections
to be uncorrelated. Accordingly, it is assumed that:
E([[epsilon].sub.is] [[epsilon].sub.it] | [X.sup.*.sub.i]) =
[[sigma].sub.st]
E([[epsilon].sub.is] [[epsilon].sub.jt] | [X.sup.*.sub.i]) = 0 (3)
for all i, j, s, t with i [not equal to] j. It should be noticed
that the heteroskedasticity and serial correlation does not vary across
cross-sections i . Using the cross-section specific residual vectors,
one may rewrite this assumption as:
E([[epsilon].sub.i] [[epsilon].sub.i]| [X.sup.*.sub.i]) =
[[OMEGA].sub.T] (4)
for all i with
[MATHEMATICAL EXPRESSION NOT REPRODUCIBLE IN ASCII] (5)
This specification involves covariances across periods within a
given cross-section, as in seemingly unrelated regressions with period
specific equations. Such a framework allows for multiple interactions
between the involved variables without imposing to rigid hypothesis
about the nature of such interlinkages.
4. THE EMPIRICAL FRAMEWORK
In order to implement the methodology, we considered a sample of
data belonging to 16 countries, members of the European Union (Greece,
Spain, Italy, Hungary, Germany, Netherlands, Belgium, Portugal, France,
Ireland, Slovenia, Great Britain, Luxemburg, Sweden, Poland and
Austria). Data was provided from Eurostat (2009) and World Federation of
Exchanges (2009) and the time span is between 2004 and 2007.
The main results are presented in the below table. Despite some
unit roots common processes at the level of the residuals (suggested
especially by the Hadri Z-stat test) the quality of the model could be
overall considered as satisfactory.
5. CONCLUSIONS AND FURTHER RESEARCH
The advanced analysis provided some empirical support for the
thesis of a positive connection between a lower cost of borrowed
resources and the economic growth (despite the fact that such a
connection seems not to be stable enough over the considered period).
As a potential further research, there can be taken into
consideration a broader range of countries belonging to European Union.
Likewise, a distinction between developed and developing countries, as
far as concerns the current state of the financial system must be done,
in order to have a more accurate analysis. Moreover, the sample can be
enlarged, using a larger time span.
6. REFERENCES
Demetriades, P. & Hussein, K. (1996). Does financial
development cause economic growth? Time-series evidence from 16
countries, Journal of Development Economics, Elsevier, vol.51(2), pg.
387-411
Demirguc-Kunt, A. (2006). Finance and economic development: policy
choices for developing countries, Policy Research Working Paper Series
3955, The World Bank
Levine, R. (1991). Stock markets, growth and tax policy, The
Journal of Finance, 46, pg.1445-65
Levine, R. & King, R. (1993). Finance and growth: Schumpeter
might be right, Quarterly Journal of Economics, MIT Press, vol. 108,
issue 3, pg. 717-37
***(2009) http://epp.eurostat.ec.europa.eu- Eurostat, Accesed on:
2009-02-28
***(2009) http://www.world-exchanges.org/-World Federation of
Exchanges, Accesed on: 2009-02-28
Tab. 1. The TSLS estimation between the dynamic of real GDP
and the considered financial variables
Dependent Variable: The dynamic of the real GDP
Method: Pooled IV/Two-stage EGLS (Cross-section random effects)
Cross-sections included: 16
Total pool (unbalanced) observations: 42
Swamy-Arora estimator of component variances
Period SUR (PCSE) standard errors & covariance (no degree of
freedom correction)
Std.
Variable Coefficient Error t-Statistic Prob.
C 673.4907 279.8444 2.406662 0.0220
DIV-2005 21.77603 19.74610 1.102801 0.2783
DIV-2006 58.63235 25.41840 2.306689 0.0277
DIV-2007 99.60585 36.69249 2.714611 0.0106
MM-2005 -78.40737 35.64972 -2.199383 0.0352
MM-2006 -20.02118 33.53529 -0.597018 0.5547
MM-2007 49.30112 57.57215 0.856336 0.3982
BM-2005 44.34550 71.77164 0.617869 0.5410
BM-2006 -12.54052 61.97273 -0.202356 0.8409
BM-2007 -91.53098 48.93977 -1.870278 0.0706
Effects Specification
Cross-section random S.D. / Rho 823.1883 0.9985
Idiosyncratic random S.D. / Rho 32.24111 0.0015
Weighted Statistics
R-squared 0.432588 Mean dependent var 16.03920
Adjusted R-squared 0.273003 S.D. dependent var 42.43189
S.E. of regression 36.17916 Sum squared resid 41885.82
Durbin-Watson stat 2.289885 Instrument rank 13.00000
