This document discusses whether stock markets promote economic growth. It begins by outlining the debate on whether financial development causes growth or vice versa. The authors then:
1) Describe previous empirical studies on the relationship between financial development/stock markets and economic growth that have limitations in establishing causality.
2) Explain their use of Granger causality tests on data from 64 countries over varying time periods to help determine the causal direction of the relationship.
3) Present sample statistics showing differences in growth rates and financial development across income levels and degrees of financial market freedom.
1. Do Stock Markets Promote Economic Growth?
By: Randall K. Filer, Jan Hanousek and Nauro F. Campos
Working Paper Number 267
September 1999
2. DO STOCK MARKETS
PROMOTE ECONOMIC GROWTH?*
Randall K. Filer
Jan Hanousek
Nauro F. Campos**
September, 1999
Abstract. One of the most enduring debates in economics is whether financial
development causes economic growth or whether it is a consequence of increased
economic activity. Little research into this question, however has used a true
causality framework. This paper fills this lacuna by using Granger-causality tests to
provide evidence of a positive and significant causal relationship going from stock
market development to economic growth, particularly for less developed countries.
Abstrakt. Jednou z d_le_itých ekonomických otázek je zda-li rozvoj finan_ního
sektoru ovliv_uje ekonomický r_st, nebo jestli je pouze následkem zvýšené
ekonomické aktivity. Tento _lánek se sna_í vyplnit mezeru v sou_asném výzkumu
t_chto kauzálních vztah_. Pomocí Grangerova testu na kauzalitu je empiricky
prokázán positivní a signifikantní kauzální vazba od rozvoje kapitálového trhu k
ekonomickému r_stu, zvlášt_ pro mén_ rozvinuté zem_.
Keywords: stock market, financial development, economic growth, Granger causality.
*
We thank Jeffrey Nugent for comments on an earlier draft, the Vienna Stock Exchange for financial support
and Aurelijus Dabušinskas, Petr Sedlák, Ji_í Sla_álek, Zden_k Halmaz_a and Dana _lábková for research assistance.
The views expressed in this paper are the authors’ alone and should not be attributed to the Vienna Stock Exchange.
**
Randall K. Filer is Professor of Economics at Hunter College and The Graduate Center of the City University
of New York and Visiting Professor of Economics at CERGE-EI, a joint workplace of Charles University and the
Academy of Sciences of the Czech Republic. Jan Hanousek is Associate Professor of Economics at CERGE-EI where
he holds the CitiBank Chair in Financial Economics. Nauro F. Campos is Assistant Professor of Economics at CERGE-
EI. All three authors are also Research Associates of the William Davidson Institute at the University of Michigan. All
may be contacted via post at CERGE-EI, P.O.Box 882, Politickych veznu 7, 111 21 Prague, Czech Republic or via e-
mail at randall.filer @cerge.cuni.cz, jan.hanousek@cerge.cuni.cz and nauro.campos@cerge.cuni.cz.
3. JEL classification: G00, G14, O16, F36.
1. Introduction
One of the most enduring debates in economics is whether financial development causes
economic growth or whether it is a consequence of increased economic activity. Schumpeter (1912)
argued that technological innovation is the force underlying long-run economic growth, and that the
cause of innovation is the financial sector’s ability to extend credit to the “entrepreneur” (see also
Hicks, 1969). Joan Robinson, on the other hand, maintained that economic growth creates a
demand for various types of financial services to which the financial system responds, so that “where
enterprise leads finance follows” (1952, p. 86).
Empirical investigations of the link between financial development in general and stock
markets in particular and growth have been relatively limited. Goldsmith (1969) reports a significant
association between the level of financial development, defined as financial intermediary assets
divided by GDP, and economic growth. He recognized, however, that in his framework there was
“no possibility of establishing with confidence the direction of the causal mechanisms (p. 48).” A
number of subsequent studies have adopted used the growth regression framework in which the
average growth rate in per capita output across countries is regressed on a set of variables controlling
for initial conditions and country characteristics as well as measures of financial market development
(see King and Levine (1993a), Atje and Jovanovic (1993), Levine and Zervos (1996), Harris (1997),
and Levine and Zervos (1998) among others).
All of these studies face a number of potential problems. In particular, they must deal with
issues of causality and unmeasured cross country heterogeneity in factors such as savings rates that
may cause both higher growth rates and greater financial sector development (see Caselli et. al
4. (1996). A number of techniques have been adopted to attempt to deal with these issues including
(a) using only initial values of financial variables (King and Levine (1993), (b) using instrumental
variables (Harris (1997)), and (c) examining cross-industry variations in growth that should be
immune to country specific factors (Demirgüç-Kunt and Maksimovic (1996) and Rajan and Zingales
(1998)).
A more difficult question arises with respect to whether the forward-looking nature of stock
prices could be driving apparent causality between stock markets and growth. Current stock market
prices should represent the present discounted value of future profits. In an efficient equity market,
future growth rates will, therefore, be reflected in initial prices. This argues for using turnover (sales
over market capitalization) as the primary measure of development, thereby purging the spurious
causality effect because higher prices in anticipation of greater growth would affect both the
numerator and the denominator of the ratio.
We address issues of causality in the framework introduced by Granger (1969). Granger
causality tests have been widely used in studies of financial markets as well as several studies of the
determinants of economic growth including savings (Carroll and Weil, 1994); exports (Rahman and
Mustafa, 1997, Jin and Yu, 1995); government expenditures (Conte and Darrat, 1988)); money
supply (Hess and Porter, 1993); and price stability (Darrat and Lopez, 1989).1
1
The studies cited are illustrative of many others looking at each potential determinant of
growth. Others have used the Granger causality framework to examine the link between factors such
as privatization, literacy and defense spending and growth.
2
5. A limited number of previous studies have used Granger causality to examine the link
between financial markets and growth. Thornton (1995) analyzes 22 developing economies with
mixed results although for some countries there was evidence that financial deepening promoted
growth. Spears (1991) reports that in the early stages of development financial intermediation
induced economic growth in Sub-Saharan Africa, while Ahmed and Ansari (1998) report similar
results for three major South-Asian economies. Finally, Neusser and Kugler (1998) report that
financial sector GDP Granger-caused manufacturing sector GDP in a sample of thirteen OECD
countries.
In summary, previous empirical research has suggested a connection between stock market
development and economic growth, but is far from definitive. Although the relationship postulated
is a causal one, most empirical studies have addressed causality obliquely, if at all. Moreover, most
studies have not adequately dealt with the fact that efficient markets should incorporate expected
future growth into current period prices.
2. Data and Methodology
Because we compare results from different countries, it is important that the data be
consistently defined across countries.2 In order to achieve as much consistency as possible, we rely
on data from the International Finance Corporation (IFC 1998 and earlier editions) for financial
2
According to a classification from the International Federation of Stock Exchanges (see the
discussion at http://www.fibv.com/) some stock exchanges count as turnover only those transactions
that pass through their trading systems while others include all transactions subject to supervision
by the market authority including those that take place off-market. In addition some sources
compute turnover as annual sales over market capitalization averaged over the past twelve months,
while others use the average of monthly sales to monthly market capitalization.
3
6. markets while growth rates and per capita GDP were obtained from International Monetary Fund’s
International Financial Statistics (various months). We were able to obtain consistent data for 64
countries for varying time periods beginning either in 1985 or the first year that the IFC reported data
for the market and ending in 1997. The list of countries used and periods covered are contained in
Table 1.3 In total, we have 847 country/year observations, although because of missing values we
use slightly over 750 observations for analyzing any given financial variable.
Stock market development is measured by three variables: (1) market capitalization over
GDP, (2) turnover velocity, and (3) the change in the number of domestic shares listed. While we
report results for whether market capitalization “causes” growth, interpretation of these results is
particularly problematic since, as discussed above, efficient markets will reflect future earnings
growth in current prices. Since earnings growth should be closely related to overall economic
growth, this will make it look like increases in market capitalization preceded and, therefore,
“caused” economic growth even if the true link ran in the reverse direction. We must, therefore,
find indicators of market development that are independent of stock prices. Given that the role of
a market is to reallocate capital to its most productive uses, the best such indicator may be the
turnover velocity (the ratio of turnover to market capitalization). Finally, we also examine the annual
percentage increase in the number of listed companies as an indication of financial deepening.
3
It should be noted that some series are not available for some countries for the full period
analyzed.
4
7. Since it is likely that the impact of stock market development on growth will vary across
levels of development we provide estimates of the causal connection for countries divided into three
groups according to per capita income.4 Finally, if financial markets promote growth, they should
be better able to do so when not distorted by government policy. Thus, we calculate an indicator of
financial market freedom based on the Heritage Foundation/Wall Street Journal 1999 Index of
Economic Freedom.5 We grouped countries according to their score on the two aspects of economic
freedom most closely related to financial markets: capital flows and foreign investment, and
banking. The first aspect ranks countries from 1 (indicating open and impartial treatment of foreign
investment and accessible foreign investment code) to 5 (where the government seeks to actively
prevent foreign investment and there is rampant corruption). The second aspect ranks countries from
1 (those with few or no government controls on domestic or foreign banks, enabling them to engage
in all types of financial services, and where there is no deposit insurance) to 5 (countries where
financial institutions are in chaos, banks operate on a primitive basis, most credit goes to state owned
enterprises, and corruption is rampant). The sample is divided into three groups according to
4
The groups are upper income countries, upper middle income countries, and other countries
(primarily lower middle income but including some lower income) according to World Bank’s 1998
classification. This classification is also the basis for the IFC’s definition of “mature” and
“emerging” markets. A country’s classification as an “emerging” or “mature” market does not
depend on the level of its stock market development or other economic institutions, but instead
merely on whether its GNP per capita is below or above the World Bank’s threshold for a “high
income country” (USD 9,656 in 1998). Although the IFC is currently considering a revision to
incorporate institutional aspects of market maturity into its definition of emerging markets, the
results of this revision are not available at this time.
5
We recognize that ideally we should use measures of economic freedom that correspond to
either the beginning of our sample period or to the entire period under study, but such measures are
not available. Were they available it is likely that they would be highly correlated with the 1999
measures.
5
8. whether the combined rating is lower than 4, equal to 5 or 6, or equal to or above 7. The lower the
score, the more financial freedom there is in the economy.6
Table 2 presents the sample statistics for the key variables for the full sample and the income
and financial market freedom subgroups. Over our time period, lower income countries grew more
rapidly than higher income ones while, because they also tend to be the richest markets, freer markets
appeared to grow less rapidly than less free ones. As might be expected, both market
capitalization/GDP and turnover/market capitalization are higher for higher income markets.
Granger causality tests rely on estimating two basic equations:
k1 k2
Y t = α 0 + ∑α i Y t - i + ∑β i X t -i + εt (1)
i=1 i=1
and
k3 k4
X t = γ 0 + ∑γ i Y t - i + ∑δ i X t -i +ν t (2)
i=1 i=1
6
We also grouped countries based on the share of domestic credit provided by the banking
sector as a percentage of GDP using data from the World Bank (1999, Table 16). Countries are
classified in three groups: if bank credit was over 80% of GDP, between 41 and 80% of GDP, and
lower than 40% of GDP. Results were inconsistent and generally insignificant across groups and
are, therefore, not reported. High bank credit may indicate an overall well-developed financial
sector, but it may also indicate countries where effective substitutes for equity markets make such
markets less important in determining growth.
6
9. where X denotes an indicator of stock market development, Y denotes economic growth and the
subscripts t and t-i denote the current and lagged values. Hsiao (1981) suggests searching over the
lag lengths (k1 to k4) and applying an information criterion to determine the optimal length of the lag
structure. We used the three most common choices of information criteria (Akaike, 1969; Hannan
and Quinn, 1979; and Schwarz, 1978) but found that more than one lag in either X or Y was never
optimal.
We must also address the fact that the presence of lagged values of the dependent variable
on the right-hand side of Equations (1) and (2) in a dynamic panel data framework can lead to
inconsistent parameter estimates unless the time dimension of the panel is very large (Nerlove
(1967), Nickell (1981) and Keane and Runkle (1992)). Anderson and Hsiao (1981) propose using
twice-lagged levels of the right-hand side variables as instruments.7 Arellano and Bond (1991)
suggest two GMM variants of the Anderson and Hsiao estimators. Kiviet (1995) suggests an
alternative approach involving direct calculation of biases and correcting of least squares estimates.
Simulation results in Judson and Owen (1996) have shown that Anderson-Hsiao estimators, while
the least biased among the available alternatives, are considerably less efficient than the alternative
proposed by Kiviet. On the other hand, extension of Kiviet’s estimator to unbalanced panels, while
conceptually possible, is computationally unfeasible. In our case, imposing the restriction that the
panel be balanced would result in a considerable loss of data since emerging markets necessarily
emerged to the point where data were available at different times.
7
They also discuss the possibility of using lagged differences as estimates, but others
(Arellano (1989) and Kiviet (1995) for example) have established the superiority of using twice-
7
10. Given the complications and efficiency loss imposed by attempting to correct for bias in
estimates of the coefficients in Equations (1) and (2) arising from the dynamic panel nature of the
data, we rely on simulations results in Judson and Owen (1999) showing that bias problems are
almost entirely concentrated in the coefficient on the lagged dependent variables, while biases in the
coefficients of independent variables (beta and delta in Equations (1) and (2)) are “relatively small
and cannot be used to distinguish between estimators [including OLS] (p. 13).” Given that we are
not interested in point estimates of these coefficients, that any biases that exist apparently work
against our finding significant causality, and that correction for biases would result in a significant
loss of efficiency that would do more damage to a search for causal relationships than a relative
small coefficient bias, we have elected to ignore bias corrections in the results that follow.
4. Results
lagged levels over lagged differences.
8
11. Equations 1 and 2 were first estimated independently for each country for which we had six
or more years of date. Given that our longest time series was only thirteen years, we were never able
to reject an hypothesis of equality of coefficients within any income or financial freedom group.
Thus, we pool observations across countries within each income and financial freedom group as well
as for the entire sample to create an unbalanced panel. We estimated both country-fixed and
random-effect models, although in every case we reject the hypothesis that the random effects are
orthogonal to the regressors (Hausman, 1978).8 Tables 3 and 4, therefore, present fixed-effect
models. The first row within each country group presents OLS regression estimates of Equation 1
for all countries and years within that group, ignoring the panel structure of the data except for
correcting the standard errors to account for heterogeneity of the residuals. The second row presents
between-country estimates in which OLS regressions were run on country-mean values, estimating
results only on the cross-country variance in the variables. The third and final row in each group
presents Least Squares Dummy Variable (LSDV) estimates, identifying the effect of financial factors
of growth only from the variance within each country (since cross-country variance is absorbed by
the country dummies).
Several results stand out in Table 3. Lagged growth rates are, in general, significant
predictors of current growth rates. This effect is quite strong for high and middle income countries
and relatively weak for lower income countries, suggesting that macroeconomic conditions are less
stable for the less developed countries in our sample. The effect relating past growth to current
growth is much more pronounced between countries than within countries, suggesting that there is
8
Results are available on request.
9
12. strong hysteresis in the pattern of growth rates across countries, even though macroeconomic
variation continues to exist within any given country. As discussed above, however, there may be
substantial bias in these coefficients, so they should be interpreted with caution.
Turning to financial variables, as expected there is a positive link between market
capitalization (normalized for the level of GDP) and future economic growth. This link, however,
is likely to be because efficient markets incorporate anticipated future growth into current period
prices and, therefore, market capitalization. Some suggestion that this may be the underlying cause
of the link between market capitalization and growth can be seen in the pattern of results across
income groups and countries. The link exists only within countries, and is more significant for
higher income countries. It is not surprising that more developed financial markets are more
efficient and, therefore, better able to incorporate anticipated future growth into current prices.
The pattern is striking with respect to turnover velocity, which, as we argued earlier, should
be a better indicator of the effect of stock markets on growth because it has been purged of forward-
looking price effects. Results suggest that a higher turnover velocity Granger-causes growth, but
only for high and low income countries. There is no effect for countries in the middle income group.
Furthermore, the location of the effect differs between the high and low income countries. For high
income countries the link between turnover velocity and growth is entirely within countries, while
for lower income countries the linkage is quite strong and is found between countries.9 This result
is particularly important. For low income countries, having a more active stock market is associated
9
We are unsure how to interpret the connection between turnover velocity within a country
and its future growth for upper-income countries. Perhaps this results from the very active markets
and rapid economic growth that have been common to OECD countries in the past few years.
10
13. with substantially higher rates of growth10. A increase of one standard deviation in stock market
activity in a low income country is associated with a 2.5 percentage point (57 per cent at the mean)
increase in growth rate. It is clear from these results that an active stock market is crucial in
reallocating capital to high value uses in developing countries. Without such a market, growth in
low and lower middle income countries is substantially lower than it could be were such an active
stock exchange to be present.
Unlike with turnover velocity, there is no evidence that a change in the number of listed
domestic companies is linked to differing rates of economic growth. Similarly, the reverse causality
relationships were almost never significant and are, therefore, not reported.11 There is one significant
exception to this generalization. Between countries in the low income group, higher growth does
appear to Granger-cause increased market capitalization. Combined with the fact that this was the
only income group for which market capitalization did not Granger-cause growth, this result
10
These results differ from those in Harris (1997) whose 2SLS results show that the link
between stock markets and growth exists only for developed countries. In OLS regressions using
lagged values to control for endogeneity, however, he finds exactly the reverse pattern, with equity
markets being important for growth only in less developed countries. Thus, the difference in results
may be largely due to the poor quality of the instruments available for use in the two-stage
procedure.
11
Again, results are available on request.
11
14. reinforces the conclusion that the link between market capitalization and growth in developed
markets is a result of efficient markets instantaneously reflecting changes in growth rates in equity
prices. In the least developed markets, where such efficiency is lacking, higher growth may actually
have to be observed before it increases stock prices.12
12
An alternative hypothesis is that international investors active in developing markets use
growth rates as a signal for the markets into which they wish to shift capital.
12
15. Table 4 repeats the analysis for subsamples of countries defined according to the degree of
freedom from government or other interference with which financial markets operate. The results
suggest an important caveat to the results in Table 3. There is a significant relationship between
lack of government interference in financial markets and income level such that two-thirds of the
observations in the lowest financial freedom category are also in the lowest income group.13 The
link between market activity and growth seen for low income countries as a whole does not apply
to this subgroup of low income countries. Indeed, there is even a hint of perverse results for these
countries, such that more active stock markets actually inhibit growth in countries where there is
little financial freedom. If we recall that one of the defining characteristics of these countries is
rampant corruption, it is possible that in these countries an active stock market is simply another
vehicle through which assets may be stolen from legitimate investors. The implication is that for
stock markets to cause growth there must first be at least a moderate degree of normality in the
operations of these markets.
13
We can speculate about the direction of causality here but offer no evidence as to whether
lack of government interference in financial markets promotes or is a consequence of growth.
13
16. 5. Conclusions
In summary, using a large number of countries with varying economic conditions and levels
of stock market activity, we find:
1) evidence that stock markets, especially in more developed economies, incorporate expected
future growth into current prices, a result that is consistent with efficient market hypotheses;
2) a strong relationship between stock market activity and future economic growth for the low
and lower middle income countries in our sample but not in higher income countries with
more developed alternative financial mechanisms; and
3) no impact of increased equity market activity on growth in developing economies where the
lack of a proper institutional framework (as evidenced by excessive corruption or
government interference in financial markets) hampers the ability of these markets to
function.
It is interesting to speculate whether this pattern of results can say anything with respect to
the various explanations that have been advanced for why there might be a connection between stock
market development and economic growth. Several possible mechanisms for such a connection have
been advanced. Among these are:
1) the fact that a more developed equity market may provide liquidity that lowers the cost of the
foreign capital that is essential for development, especially in low income countries that
cannot generate sufficient domestic savings (WIDER (1990), Bencivenga et. al. (1996), and
Neusser and Kugler (1998)).
14
17. 2) the role of equity markets in providing proper incentives for managers to make investment
decisions that affect firm value over a longer time period than the managers’ employment
horizons through equity-based compensation schemes (Dow and Gorton (1997)).
3) the ability of equity markets to generate information about the innovative activity of
entrepreneurs (King and Levine (1993b) or the aggregate state of technology (Greenwood
and Jovanovic (1990)).
4) the role of equity markets in providing portfolio diversification, enabling individual firms
to engage in specialized production, with resulting efficiency gains ( Acemoglu and Zilibotti
(1997)).
5) the fact that diverse equity ownership creates a constituency for political stability, which, in
turn, promotes growth (Perotti and van Oijen (1999)).
All of these channels (and many others) are likely to play a role. The fact that the links are
stronger in low income countries points especially to the role of equity markets in attracting foreign
capital while the link between political institutions and the ability of stock markets to promote
growth suggests that the last may also play an important role.
From these results it is clear that an active equity market is an important engine of economic
growth in developing countries. Public policy and international aid directed toward introducing and
fostering such markets while creating an institutional framework that is free of corruption and
excessive government control should have a large impact in increasing long-term growth rates and
economic well-being in much of the world.
15
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WIDER.
World Bank. 1999. World Development Report 1998/99: Knowledge for
Development. Washington, D.C.: Oxford University Press.
19
22. Table 1
Countries Included in Analysis by Income Category and Years Available
High Income Group Upper Middle Income Low Middle and Low Income
Country Time span Country Time span Country Time span
Australia 1985-1997 Argentina 1985-1997 Bangladesh 1985-1997
Austria 1985-1997 Botswana 1991-1997 China 1991-1997
Belgium 1985-1997 Brazil 1985-1997 Columbia 1985-1997
Canada 1985-1997 Chile 1985-1997 Ecuador 1993-1997
Denmark 1985-1997 Czech Republic 1994-1997 Egypt 1985-1997
Finland 1985-1997 Hungary 1991-1996 India 1985-1997
France 1985-1997 Malaysia 1985-1997 Indonesia 1985-1997
Germany 1985-1997 Mauritius 1990-1997 Iran 1991-1996
Hong Kong 1985-1997 Mexico 1985-1997 Jamaica 1986-1997
Iceland 1994-1997 Oman 1989-1997 Jordan 1986-1997
Ireland 1994-1997 Poland 1991-1997 Kenya 1989-1997
Italy 1985-1997 Saudi Arabia 1991-1996 Morocco 1985-1997
Japan 1985-1997 Slovakia 1994-1997 Namibia 1993-1996
Luxemburg 1985-1992 South Africa 1985-1997 Nigeria 1985-1997
Netherlands 1985-1997 Trinidad Tobago 1985-1997 Pakistan 1985-1997
New Zealand 1985-1997 Turkey 1987-1997 Panama 1992-1997
Norway 1985-1997 Uruguay 1985-1997 Paraguay 1993-1996
Singapore 1985-1997 Venezuela 1985-1997 Peru 1985-1997
Spain 1985-1997 Philippines 1985-1997
Sweden 1985-1997 Sri Lanka 1985-1997
Switzerland 1985-1997 Thailand 1985-1997
UK 1985-1997 Tunisia 1985-1997
US 1985-1997 Zimbabwe 1985-1997
Cyprus 1991-1997
Greece 1985-1997
Israel 1985-1997
Korea 1985-1997
Portugal 1985-1997
20
23. Table 2
Sample Characteristics
Market Turnover/ Change in No.
Group Statistics GDP growth Cap/GDP Market Cap of Companies
Mean 3.8 41.28 0.33 -47.43
Std. Error 3.86 59.56 0.37 902.17
All Countries No. of obs. 847 762 761 753
Mean 3.28 58.75 0.44 -12.64
High Std. Error 2.79 71.39 0.38 126.3
Income No. of obs. 358 337 333 336
Mean 3.9 40.54 0.29 -10.82
Upper Middle Std. Error 4.5 60.24 0.35 140.99
Income No. of obs. 197 179 179 172
Lower Middle Mean 4.38 17.87 0.2 -98.95
and Low Std. Error 4.42 20.56 0.32 1556.76
Income No. of obs. 292 246 249 243
Mean 3.22 53.34 0.33 -21.94
High Financial Std. Error 3.7 72.63 0.31 278
Freedom No. of obs. 382 339 334 338
Medium Mean 4.35 34.04 0.35 -19.02
Financial Std. Error 3.81 46.9 0.43 246.82
Freedom No. of obs. 391 365 365 356
Mean 3.88 16.33 0.17 5.71
Low Financial Std. Error 4.56 14.01 0.17 24.33
Freedom No. of obs. 74 58 62 58
21
24. Table 3
Tests of Granger Causality Running from Financial Variables to Growth
(Countries Grouped by Income)
X = Turnover/ X = Change in No. of
X = Market Cap/GDP Market Cap Companies
Group Lagged Y Lagged X Lagged Y Lagged X Lagged Y Lagged X
.420** .003* .419** .956** .459** -.002*
Total (.042) (.001) (.042) (.314) (.045) (.0001)
.646** .002 .586** 1.90** .893** -.003
Between (.078) (.004) (.073) (.710) (.036) (.003)
.159** .007** .293** 1.04* .209** .000004
All Countries Within (.050) (.002) (.035) (.431) (.058) (.000005)
.618** .003* .609** .886* .631** -.0004
Total (.060) (.001) (.059) (.438) (.058) (.009)
1.073** -.005 1.058** -.248 .959** .001
Between (.023) (.677) (.024) (.200) (.054) (.003)
High .315** .005** .303** 1.332** .349** -.0004
Income Within (.076) (.002) (.077) (.433) (.075) (.001)
.336** .007* .363** .281 .373** .002
Total (.078) (.004) (.077) (.755) (.086) (.001)
.812** .001 .701** 1.393 .894** -.002
Between (.086) (.005) (.099) (1.363) (.100) (.005)
Upper Middle .071 .010+ .094 .308 .238** .002
Income Within (.095) (.005) (.097) (.838) (.079) (.002)
.302** .006 .222** 3.397** .380** -.0001**
Total (.073) (.012) (.074) (.777) (.082) (.00001)
.301 -.004 -.195 7.848** .846** -.0003
Lower Middle Between (.182) (.032) (.131) (1.221) (.059) (.0003)
and Low .131+ .013 .157+ -.759 .220** -.00001
Income Within (.080) (.013) (.081) (1.056) (.098) (.00002)
** = Significant at the 1% confidence level
* = Significant at the 5% confidence level
+ = Significant at the 10% confidence level
22
25. Table 4
Tests of Granger Causality Running from Financial Variables to Growth
(Countries Grouped by Financial Freedom)
X = Turnover/ X = Change in No. of
X = Market Cap/GDP Market Cap Companies
Group Lagged Y Lagged X Lagged Y Lagged X Lagged Y Lagged X
.420** .003* .419** .956** .459** -.002*
Total (.042) (.001) (.042) (.314) (.045) (.0001)
.646** .002 .586** 1.90** .893** -.003
All Countries Between (.078) (.004) (.073) (.710) (.036) (.003)
.159** .007** .293** 1.04* .209** .000004
Within (.050) (.002) (.035) (.431) (.058) (.000005)
.409** .004* .434** .637 .478** -.001
Total (.062) (.002) (.062) (.427) (.070) (.0004
.763** .001 .691** 1.219 .891** -.0004
Between (.080) (.003) (.077) ( .975) (.069) (.002)
High Financial .212** .005** .233** 1.100 .296** -.001**
Freedom Within (.074) (.002) (.076) (.502) (.089) (.0003)
.442** .004 .418** 1.211** .478** -.001*
Total (.064) (.003) (.064) (.454) (.063) (.0002)
.547** .004 .430** 2.699* .916** -.0004
Medium Between (.143) (.010) (.139) (1.132) (.045) (.002)
Financial .113 .011* .129* .237 .171* -.001
Freedom Within (.075) (.005) (.075) (.644) (.078) (.0003)+
.187 -.030 .176+ 1.331 .219* -.002
Total (.087) (.031) (.090) (2.032) (.099) (.010)
1.117* -.018 1.347* -2.724 .936** .007
Between (.270) (.030) (.262) (2.797) (.094) (.041)
Low Financial .013 .019 .003 -5.013+ -.045 .002
Freedom Within (.113) (.047) (.121) (2.645) (.164) (.006)
** = Significant at the 1% confidence level
* = Significant at the 5% confidence level
+ = Significant at the 10% confidence level
23