An empirical examination of international diversification benefits in Central European emerging equity markets.

Fadhlaoui, Kais ; Bellalah, Makram ; Dherry, Armand 等

ABSTRACT

The objective of this paper is to examine the short and long-term relationships between the seven developed equity markets of United-States, Canada, United-Kingdom, France, Germany, Italy, Japan and three Central European emerging equity markets of Czech-Republic, Hungary and Poland in order to study their implications on the potential gains from international diversification in these emerging markets. The shortterm relationships measured by the correlation matrix indicate a lower level of correlation between developed and emerging equity markets of Central Europe. In order to carry out the long-term relationships we resorted to Johansen cointegration techniques recently developed. The tests show that there is no long-term relationship between G7 developed equity markets and Central European emerging equity markets. Theses results indicate that the increase of financial integration degree and co-movement between equity markets has not significantly affected the expected benefits from international diversification in these emerging markets. These gains remain significantly important for the G7 industrial investors in the Central European emerging equity markets.

JEL Classification: F21, G15

Keywords: International portfolio diversification; Financial integration; Central European emerging markets; Cointegration theory

I. INTRODUCTION

International portfolio diversification was started in with the decision of Morgan Guaranty in 1974 to invest a part of its pension fund outside the United-States. At that time, the US market lived tow successive decreases in 1973 and 1974, but outside the United-States, the returns had been very attractive. Accordingly, the investors have become increasingly more active in foreign capital markets. The investment in international financial market knows a spectacular increase. Recently, as a consequence of market liberalisation, financial markets tended to become more integrated. This integration process implies the increase of correlation between financial markets which can have negative effects on benefits from international diversification. This later depends on markets correlations. If the correlation coefficients between markets are higher, the gains from international diversification are low. On the other hand, if the market correlation is low the gain is very important.

The higher integration between developed markets led us to study the important potential of emerging markets for international portfolio diversification. However, the financial crises especially in Asia and Latin America emerging markets led investors to search for other emerging markets (Flight to quality phenomenon) like the Central Europe emerging markets. Those markets can provide more opportunities to increase benefits from international diversification. The endeavour to bring these economies into line with the western European economies gives them an important priority and led investors to study these investment opportunities.

This study examines the possible benefits from international diversification for the seven developed countries of United-States, Canada, United-Kingdom, France, Germany, Italy, and Japan in the three important emerging equity markets of Central Europe, those of the Czech Republic, Hungary and Poland.

The remainder of the paper is structured as follows; Section II discusses the relevant literature. Section III presents the methodology and the data. Section IV reports our empirical results and Section 5 contains our conclusions.

II. LITERATURE REVIEW

Advantages of International portfolio diversification are inversely related to the correlations between equity markets returns. The international diversification gains decline as the correlations between securities returns become increasingly positive. However, the existence of low correlations between national markets can provide significant benefits from international diversification. Numerous researches have recognized low correlation between international capital markets and highlight the substantial international diversification gains. The early literature in this field, like for example, Grubel (1968), Levy and Sarnat (1970), and Lessard (1973) finds low correlation between developed and emerging equity markets it proves that the benefits from international diversification is considerable for investors of industrial countries in emerging markets.

Other recent studies document the importance of low correlation between developed and emerging markets for generating substantial benefits from international diversification (Eun and Resnick (1984), Errunza and Padmanabhan (1988), Meric and Meric (1989), Bailey and Stulz (1990), Divecha et al. (1992), and Phylaktis et Ravazzolo (2005)). Many factors can explain the low correlations and consequently the importance of emerging markets in international portfolio diversification strategies: barriers to foreign investment flows on emerging markets in order to preserve the control of national companies; the asymmetric information on securities in emerging markets; strong controls of exchange and the lack in free trade of emerging markets with international markets.

Several authors have used the cointegration techniques to examine the existence of linkages and long term co-movements between developed and emerging markets. They examine their effects on the benefits of international diversification for investment in emerging markets. Kasa (1992) and Arshanapalli and Doukas (1993) prove an evidence of bi-variate cointegration relationship between American and European equity markets. The existence of such linkage affects negatively the benefits of international diversification for US investors in those European markets.

Harvey (1995b) finds that assets in emerging markets provides for American investors high expected returns and low level of risk. He argues that the main interest of emerging markets for a portfolio manager rests in reducing the risk, but not in the enhancement of returns. This result gives an explanation to the low correlation between emerging markets, and with the global markets in comparison with the correlations between developed markets.

DeFusco et al. (1996) show the non-existence of short-term and long-term linkages between the American market and thirteen emerging equity markets in the Pacific Basin, Latin America and the Mediterranean regions. They confirm that these markets are not cointegrated between them. They conclude that this segmentation between US market and these emerging markets in these three regions indicates the possible existence of international diversification benefits in short and long term across theses markets.

Bekaert and Urias (1996) reject the assumption that equity indices in developed countries span the mean-variance frontier of all international equity indices. They prove the existence of gains from international diversification in emerging equity markets. De Santis and Gerard (1997) assess, by using the international capital asset pricing model (ICAPM), that the expected gain from international diversification is on average 2.11 percent yearly for an American investor.

Li et al. (2003) used Bayesian inference approach to examine the impact of short-sale constraints on the existence and the magnitude of the gains from international diversification for American investors in eight emerging equity markets of four Latin American markets (Argentina, Brazil, Chile, and Mexico) and four South-East markets (Hong Kong, South Korea, Singapore, and Thailand). They show that the benefits of international diversification remain substantial for American investors after imposing short-sale constraints on emerging equity markets but not after imposing short-sale constraints on G7 developed equity markets. The authors conclude that the integration of world equity markets reduces, but does not eliminate, the benefits of international diversification in emerging equity markets subject to short-sale constraints. These results reinforce the "home bias puzzle" with respect to investments in emerging markets.

Gilmore and McManus (2005) examine the diversification benefits for American investors in the emerging equity markets of Central Europe (Czech Republic, Hungary and Poland). They conclude that American investors can get a higher level of returns from diversifying their portfolio in Central European equity markets since there are not short-term and long-term linkages between theses markets and US market.

Lagoarde and Lucey (2006) investigate the presence of international portfolio diversification benefits in the most important equity markets of the Middle East and North Africa (MENA) region. Their results show the presence of higher potential of international diversification benefits in this region, whether transaction are denominated in local currencies or in U.S dollars. Furthermore, the portfolio with minimum variance appears as the most promising optimization technique. In addition, portfolios based on local currencies seem to exhibit a higher degree of diversification, while the measure of risk seems to affect profitability less than the optimization model employed. Overall, they show that these under-estimated and under-investigated markets of MENA region should attract more portfolio flows in the future.

Despite the existence of numerous studies about capital market integration between developed and emerging equity markets and their effects on the gains from international diversification, a little attention is given to the investment possibility in Central European equity markets. These markets were isolated under the communist regime for a long period from external influences until the 1990s, date of their reemergence on international financial arena. The increasing economic growth of these equity markets and their attempt to open their financial markets to foreign investment led us to spare them a particular attention. This research explores the issue of investment opportunities and the possible benefits from international diversification for seven industrial countries in the three main major Central European equity markets of Czech-Republic, Hungary and Poland; we use the recent development of cointegration theory.

III. METHODOLOGY AND DATA

A. Methodology

We use the cointegration approach in order to study first the interdependence relationship between developed markets, and Central European emerging equity markets, and then, to examine the issue of likely benefits of international diversification in this region. This latter allows us to detect a long run co-movement between index series. This co-movement implies the integration between national markets which affect negatively the diversification benefits. The cointegration test examines the stationarity of equity index series. In this way, all series must be non-stationary and integrated of the same order: it is a necessary condition for doing a cointegration analysis. Therefore, we use the Augmented Dickey Fuller (ADF) and Phillips-Perron (PP) test.

Appropriate lag lengths of vector autoregression used to determine the maximal order of integration were selected according to the Akaike Information Criterion (AIC) and Schwarz Criterion (SC). After and to determine whether the time series are cointegrated we resort to the Johansen test (1988). The latter allows us to know the number of cointegrated vector of the index series. The existence of long run relationship between series leads to the study of short run relationship by the VECM model. Finally, the Granger causality test (1969) is used to identify the causality sense between index series.

B. Data

The data used in this study consist of daily price indices time series for three Central European emerging stock markets (Czech-Republic, Hungary and Poland), and seven developed stock markets (United-States, Canada, United-Kingdom, France, Germany, Italy, and Japan). The time period covers October 1, 2000, through September 30, 2006, which gives a total of 1565 observations for each market. Indices were obtained from the Morgan Stanley Capital International Data Base (MSCIDB1) and all the index series are in US dollars terms. We use stock prices in US dollars in order to eliminate the problem of exchange rate variations (especially between developed and emerging markets).

IV. EMPIRICAL RESULTS

A. Descriptive Statistics

Table 1 provides the descriptive statistics for daily stock returns of markets examined in this study: United-States, Canada, United-Kingdom, France, Germany, Italy, Japan, Czech-Republic, Hungary, Poland. The Czech Republic stock index shows the higher average returns (0,001472) than all other markets (the US market shows the low average returns (-0,000173)). The maximum return vary between (0,038562) in Canada stock market and (0,08372) in the Hungarian market. The minimum return fluctuate between (-0,08963) in the Canadian market to (-0,05017) in the US. The German stock index shows the higher level of risk measured by the standard deviation (0,016138), followed by Poland stock index for the emerging markets (0,015985). The markets of Canada, United-Kingdom and United-States show the low level of risk (respectively: (0,012472), (0,012528) and (0,012807)). The Kurtosis and Skewness statistics indicate that index returns series are leptokurtic and have an asymmetric distribution that rejects significantly the null hypothesis of normality for all the index returns series.

B. Correlation Coefficients between Equity Return Series

Table 2 reports the correlation coefficients between equity return series of developed and emerging equity markets for daily frequencies. The results show positive and higher correlation coefficients between developed markets. The higher correlation is noted between France and United-Kingdom markets (89,84%) followed by the pair of Germany-France (88,221%). The low correlation level is between Japan and Germany (12,021%). We find low correlation coefficients between emerging and developed equity markets. They vary from (10,126%) between US and Czech Republic market to (38,681%) between Hungary and Czech Republic market.

The correlation coefficients indicate that developed markets are more integrated between them, but they are segmented with the emerging equity markets of Central Europe in the short-term. This result shows that there are still some diversification benefits from investment in emerging equity markets of Central Europe in the short run. We investigate further through cointegration techniques whether theses short-term dependences are appropriate indicators for international diversification benefits in the long-term investment in Central European emerging equity markets.

C. Unit Roots Tests for Stock Prices

Unit root tests developed by Phillips (1987 (4)), Perron (1988 (5)) and augmented by Dickey--Fuller (1981) (Extension of Dickey and Fuller, 19796) are used for examining the time series stationarity. The presence of unit root in time series of stock prices indicates that series are non-stationary

1. Augmented Dickey--Fuller (ADF) tests

- Model 1 standard (7)

[DELTA][Y.sub.t] = [rho][Y.sub.t-1] - [p.summation over (j=2)][[pi].sub.j][DELTA][Y.sub.t-j+1] + [[epsilon].sub.t]

- Model 2 with intercept (8)

[DELTA][Y.sub.t] = [rho][Y.sub.t-1] - [p.summation over (j=2)][[pi].sub.j][DELTA][Y.sub.t- j+1] + c + [[epsilon].sub.t]

- Model 3 with intercept and trend (9)

[DELTA][Y.sub.t] = [rho][Y.sub.t-1] - [p.summation over (j=2)][[pi].sub.j][DELTA][Y.sub.t-j+1] + c + bt +[[epsilon].sub.t]

Avec : [[epsilon].sub.t] [right arrow] iid

Under alternative hypothesis [absolute value of [[pi].sub.1]] < 1, augmented Dickey--Fuller (ADF) tests are based on estimation by ordinary least-squares OLS regression of the tree following models.

2. The Phillips--Perron (PP) test

The Augmented Dickey Fuller (ADF) test assumes that errors are statistically independent and have a constant variance. To overcome this limitation, Phillips and Perron (1988) developed an alternative test which represents a generalization of the Dickey-Fuller test. The advantage of Phillips-Perron test consists of allowing the error disturbances to be weakly dependent and heterogeneously distributed. The Phillips-Perron (1988) model is as follows:

[y.sub.t] = [[alpha].sub.0] + [[alpha].sub.1][y.sub.t-1] + [[alpha].sub.2] (t - T/2) + [[mu].sub.t]

Where T is the observations number and the disturbance term [[mu].sub.t] is such that E ([[mu].sub.t] = 0. The ordinary least squares method is used to estimate the equation. The t-statistic of the [[alpha].sub.1] coefficient is corrected for serial correlation in [[mu].sub.t] using the Newey-West (10) procedure for adjusting the standard errors. Table 3 presents the results for the ADF and PP unit root tests applied to the levels and first differences of each series of daily price indices.

For the series in level, the null hypothesis of a unit root cannot be rejected at the tree confidence level. On the other hand, the series in first difference reject the null hypothesis of unit root. This result indicates that all the series of daily price indices is stationary in first difference and consequently they follow I(1) processes (integrated of order one, I(1)).

D. Johansen Cointegration Test

The Johansen 1988 method relies on the relationship between the rank of a matrix and its characteristic roots (or eigenvalues).

Let [X.sub.t] be a vector of n time series variables, each of which is integrated of order (1) and assume that [X.sub.t] can be modeled by a vector autoregression (VAR):

[X.sub.t] = [A.sub.1][X.sub.t-1] + ..... + [A.sub.p][X.sub.t-p] + [[epsilon].sub.t] (1)

Rewrite the VAR as:

[DELTA][X.sub.t] = [PI][x.sub.t-1] + [summation][GAMMA][DELTA][x.sub.t-i] + [[epsilon].sub.t] (2)

[PI] = [summation][A.sub.i] - I, [[GAMMA].sub.i] = - [summation][A.sub.i].

If the coefficient matrix [PI] has reduced rank r < k, there exist k x r matrices [alpha] and [beta] each with rank r such that [PI] = [alpha] [beta]' and [beta]'[x.sub.t] is stationary. The number of cointegrating relations is iven r, and each column of [beta] is a cointegrating vector. At this level three cases are possible

* First, if [PI] is of full rank, all elements of X are stationary and none of the series has a unit root.

* Second, if the rank of [PI] = 0, there are no combinations which are stationary and there are no cointegrating vectors.

* Third, if the rank of {PI] is r such that 0 < r < k , then the X variables are cointegrated and there exist r cointegrating vectors. Eq. (1) can be modified to allow for an intercept and a linear trend.

The number of distinct cointegrating vectors can be obtained by determining the significance of the characteristic roots of [PI]. To identify the number of characteristic roots that are not different from unity, we use two statistics: the trace test and the maximum eigenvalue test given by:

[PI][[lambda].sub.trace] (r) = - T [summation]In (1 - [[lambda].sub.ti] (3)

[[lambda].sub.max] (r, r + 1) = - T In (1 - [[lambda].sub.r+1]) (4)

Where [[lambda].sub.i] equals the estimated values of the characteristic roots (eigenvalues) obtained from the estimated [PI] matrix, r is the number of cointegrating vectors, and T is the number of usable observations.

The trace test evaluates the null hypothesis that the number of distinct cointegrating vectors is less than or equal to r against a general alternative. The maximum eigenvalue test examines the number of cointegrating vectors.

If the variables in [X.sub.t] are not cointegrated, the rank of [PI] is equal to zero and all the characteristic roots are equal to zero. Given that In(1)=0, each of the expressions In(1 - [[lambda].sub.i]) will equal zero in that case. Critical values for the test are provided by Johansen and Juselius (1990) (12) and by Osterwald-Lenum (1992) (13).

We use the Johansen (1988) cointegration test to investigate the existence of long-run relationship between developed equity markets and Central European emerging equity markets. The lag structures of vector autoregression model were chosen according to the Akaike Information Criterion (AIC) and Schwarz Criterion (SC). A multilateral Johansen test was applied to the Central European equity markets as a group. The results reported in table 4 indicate no evidence for a multilateral cointegration relationship between these markets. This reveals the absence of long-run stable equilibrium relationship between these markets. We can explain this absence of cointegration vector between Central European equity markets by their segmentation on the long-run. Hence these markets don't have a higher risk between them. Also, there are substantial benefits from international portfolio diversification in the equity markets of Central Europe.

The Johansen bivariate cointegration tests between emerging markets (of central Europe) and the G7 developed markets, presented in Table 5, 6 and 7 below, show the absence of bilateral cointegration relationship between the groups of those markets. This result implies the segmentation of this emerging European market with developed markets. These conclusions confirm the results in Gilmore and McManus (2002) (for the Emerging markets of central Europe). They report the segmentation of this group of markets especially with the US market. Hence, US investors with longer-term investment horizons can benefit from diversifying into the Central European equity markets.

These results can be explained first by the recent emergence of these markets (on international financial arena) after their liberation from the communist regime in the 1990. Second, they can be explained by the weak of economic and financial relationship between the economy of this country as a group and with the economy of developed country.

Other factors can explain the segmentation between developed and the emerging markets of central Europe. First, emerging markets of central Europe opened their economy under some conditions, which are very different from those of the United States and Western Europe. This period has been characterised by the transition from planned economies to market economies and by extensive waves of privatization of state-owned companies. Each central European country has tried to liberalize their economy and opened their frontier to international capital flows to attract global investors but they are not yet fully integrated into the international economy. So, it is not surprising that their equity markets would not provide evidence of long-term co-movements with the G7 developed market.

V. CONCLUSION

This paper examines the relationship between the G7 developed capital markets and the emerging markets of Central Europe. Bivariate and multivariate cointegration techniques (Johansen cointegration test (1988)) are used in our analysis. Central European markets started a process of liberalisation of their economies in the beginning of the 1990, to start their integration of European Union. This liberalisation process allows these countries to attract foreign investors and to increase the international capital flows to these markets. The results of cointegration tests showed that the emerging markets of central Europe are segmented as a group and are segmented with the G7 developed markets. The results of our tests reveal that emerging markets can provide substantial gains from international diversification especially for the investors of industrialised countries. We are extending these tests to other countries.

REFERENCES

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Gilmore, C.G., McManus, G.M., and Tezel, A., 2005b, "Should Investors Diversify into the Central European Equity Markets?" In: Columbus, F. (Ed.), Politics and Economics of Eastern and Central Europe (Nova Science), in press.

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ENDENOTES

(1.) Morgan Stanley Capital International (www.msci.com)

(2.) Index returns are estimated as the log-relative of daily prices for October 1, 2000, through September 30, 2006 using the MSCI indices for all markets in the sample : [Return.sub.t] = Ln (I.sub.t]/[I.sub.t-1])

(3.) The Jarque-Bera statistic tests the null hypothesis of a normal distribution and is distributed as a [X.sup.2] with 2 d.f. Jarque. C. M et Bera. A. K, (1984), <<Efficient tests for normality homoscedasticity and independence of regression residuals >>, Economic Letter, Vol 6, p.255-259

(4.) Phillips, P. C. B. (1987), "Time series regression with a unit root", Econometrica, no 55, p. 277-301.

(5.) Perron, P. (1988), "Trends and random walks in macroeconomic time series: Further evidence from a new approach", Journal of Economic Dynamics and Control, no 12, p. 297- 332.

(6.) Dickey, D. and Fuller, W. (1979), "Distribution of the estimators for autoregressive time series with a unit root", Journal of the American Statistical Association, no 74, p. 427-431.

(7.) [y.sub.t] is a pure random walk if t [rho] = 0

(8.) [y.sub.t] is a random walk with a drift if [rho] = 0

(9.) [y.sub.t] is a random walk with a drift and linear time trend if [rho] = 0

(10.) Newey, W. and West, K., (1987), "Hypothesis testing with efficient method of moments estimation", International Economic Review, no 28, p.777-787.

(11.) The critical values are based on MacKinnon 1991. MacKinnon, J.G., (1991), "Critical values for cointegration tests in long-run econometric relationships. In: Engle, R.F., Granger, C.W.J. Eds.", Readings in Cointegration. Oxford, New York.

(12.) Johansen, S. and Juselius, K., (1990), "Maximum likelihood estimation and inferences on cointegration with applications to the demand for money". Oxford Bulletin of Economics and Statistics, no 52, p. 169-210.

(13.) Osterwald-Lenum, M. (1992), "A note with quantiles of the asymptotic distribution of the maximum likelihood conintegration rank test statistics", Oxford Bulletin of Economics and Statistics, no 54, p. 461-472.

Kais Fadhlaouia, Makram Bellalahb, Armand Dherryc, and Mhamed Zouaouild

(a) PhD Student in Finance University of Amiens, CRIISEA-FOM, kais.fadhlaoui@yahoo.fr

(b) Assistant Professor University of Amiens, CRIISEA-FOM, makram.bellalah@u-picardie.fr

(c) Professor of Finance, ESG Paris

(d) Professor of Management, ESC Tunis, Tunsia

Table 1
Summary statistics of daily equity return (2) series

The Jarque-Bera test (3) for normality rejects the null
hypothesis that all the stock index and return series follow
a normal distribution.

 Markets
Statistic
 US Canada UK France

Mean -0,000173 0,000179 0,000048 0,00000386
Median 0,000394 0,000594 0,000004 0,000327
Maximum 0,06428 0,038562 0,047372 0,05897
Minimum -0,05017 -0,08963 -0,05452 -0,06382
S.D 0,012807 0,012472 0,012528 0,014938
Skewness 0,13854 -0,91837 -0,38674 -0,11837
Kurtosis 532,546 78,539 63,692 514,836
Jarque.Bera 3,649,372 2,216,438 4,286,039 2,875,639
Probability 0 0 0 0
N 1565 1565 1565 1565

 Markets
Statistic
 Germany Italy Japan

Mean -0,0000473 0,00016 -0,0000739
Median 0,000374 0,000628 -0,0000318
Maximum 0,06986 0,06572 0,04938
Minimum -0,07567 -0,06127 -0,07027
S.D 0,016138 0,013772 0,014893
Skewness -0,14621 -0,56738 -0,15718
Kurtosis 510,326 67,382 493,872
Jarque.Bera 2,768,372 463,137 1,827,639
Probability 0 0 0
N 1565 1565 1565

 Markets
Statistic Czech
 Republic Hungary Poland

Mean 0,001472 0,001138 0,000631
Median 0,001427 0,001038 0,000683
Maximum 0,05679 0,08372 0,05862
Minimum -0,07268 -0,07849 -0,05283
S.D 0,01562 0,015831 0,015985
Skewness -0,28603 -0,1773 0,078329
Kurtosis 487,382 49,821 443,082
Jarque.Bera 1,398,452 1,881,483 2,684,372
Probability 0 0 0
N 1565 1565 1565

Table 2
Correlation coefficients between daily equity return series

 US Canada UK France Germany

US 100% 74,4% 65,1% 54,0% 68,2%
Canada 100% 47,4% 49,3% 62,3%
UK 100% 89,9% 78,6%
France 100% 88,2%
Germany 100%
Italy
Japan
Czech
Republic
Hungary
Poland

 Czech
 Italy Japan Republic Hungary Poland

US 39,4% 13,6% 10,1% 13,7% 15,1%
Canada 33,8% 16,8% 19,3% 21,2% 20,1%
UK 69,3% 20,2% 21,4% 12,2% 22,1%
France 81,1% 19,0% 23,6% 27,1% 14,5%
Germany 76,7% 12,0% 18,2% 23,5% 21,2%
Italy 100% 15,6% 22,4% 24,4% 35,5%
Japan 100% 17,5% 18,5% 14,4%
Czech
Republic 100% 38,7% 36,6%
Hungary 100% 37,9%
Poland 100%

Table 3
Unit root tests for daily stock indices

 Country Index level
Models Index
 ADF PP

Model 3 Canada -2.264903 -2.258452
with UK -1.863192 -1.427318
intercept France -1.895273 -1.769420
& trend Italy -1.764284 -1.563829
 Japan -2.351846 -2.284395
 Poland -1.742816 -1.537291
 -3.965104 -3.965104
 (a 1%) (a 1%)
 Critical -3.413264 -3.413264
 Values (a 5%) (a 5%)
 (11) -3.128656 -3.128656
 (a 10%) (a 10%)

Model 2 US -2.417319 -2.371252
with -3.435157 -3.435157
intercept (a 1%) (a 1%)
 Critical -2.86355 -2.86355
 Values (a 5%) (a 5%)
 -2.56789 -2.56789
 (a 10%) (a 10%)

Model 1 Germany -1.382117 -1.373142
standard Czech
 Republic 2.361401 2.584261
 Hungary 4.772143 4.561938
 -2.566738 -2.566738
 (a 1%) (a 1%)
 Critical -1.941067 -1.941067
 Values (a 5%) (a 5%)
 -1.616536 -1.616536
 (a 10%) (a 10%)

 Country First differences
Models Index
 ADF PP

Model 3 Canada -32.63104 -32.84216
with UK -33.74201 -35.83217
intercept France -35.483162 -35.63062
& trend Italy -35.67931 -35.73195
 Japan -34.87524 -34.92651
 Poland -32.48013 -32.51392
 -3.965115 -3.965109
 (a 1%) (a 1%)
 Critical -3.413269 -3.413266
 Values (a 5%) (a 5%)
 (11) -3.128659 -3.128657
 (a 10%) (a 10%)

Model 2 US -36.17431 -36.41254
with -3.435161 -3.435161
intercept (a 1%) (a 1%)
 Critical -2.863552 -2.863552
 Values (a 5%) (a 5%)
 -2.567891 -2.567891
 (a 10%) (a 10%)

Model 1 Germany -36.57124 -36.58847
standard Czech
 Republic -35.39842 -35.23614
 Hungary -33.78935 -33.47832
 -2.566739 -2.566739
 (a 1%) (a 1%)
 Critical -1.941067 -1.941067
 Values (a 5%) (a 5%)
 -1.616536 -1.616536
 (a 10%) (a 10%)

Table 4
The Johansen multilateral cointegration test

Sample (adjusted): 10/05/2000 9/30/2006
Included observations: 1563 after adjustments
Series: Czech Republic Hungary Poland

 5 Percent 1 Percent
Hypothesized Trace Critical Critical
No. of CE(s) Eigenvalue Statistic Value Value

None 0.032427 26.24813 29.68 35.65
 At most 1 0.004138 11.63132 15.41 20.04
 At most 2 0.007648 2.317035 3.76 6.65

Trace test indicates no cointegration at both 5% and 1% levels

*(**) denotes rejection of the hypothesis at the 5%(1%) level

Table 5
Bilateral Johansen cointegration tests Results

Sample (adjusted): 10/05/2000 9/30/2006
Included observations: 1563 after adjustments
Trend assumption: Linear deterministic trend
Series: US Czech Republic
Lags interval (in first differences): 1 to 1

Hypothesized Trace Trace
No. of CE(s) Eigenvalue Statistic Statistic 1% CV

None 0.052471 12.14213 15.41 20.04
At most 1 0.025146 3.113523 3.76 6.65

*(**) denotes rejection of the hypothesis at the 5%(1%) level
Trace test indicates no cointegration at both 5% and 1% levels

Sample (adjusted): 10/05/2000 9/30/2006
Included observations: 1563 after adjustments
Trend assumption: Linear deterministic trend
Series: US Hungary
Lags interval (in first differences): 1 to 1

Hypothesized Trace Trace
No. of CE(s) Eigenvalue Statistic Statistic 1% CV

None 0.051347 10.41572 15.41 20.04
At most 1 0.023531 2.739193 3.76 6.65

*(**) denotes rejection of the hypothesis at the 5%(1%) level
Trace test indicates no cointegration at both 5% and 1% levels

Sample (adjusted): 10/05/2000 9/30/2006
Included observations: 1563 after adjustments
Trend assumption: Linear deterministic trend
Series: US Poland
Lags interval (in first differences): 1 to 1

Hypothesized Trace Trace
No. of CE(s) Eigenvalue Statistic Statistic 1% CV

None 0.054729 13.63912 15.41 20.04
At most 1 0.017835 3.382481 3.76 6.65

*(**) denotes rejection of the hypothesis at the 5%(1%) level
Trace test indicates no cointegration at both 5% and 1% levels

Sample (adjusted): 10/05/2000 9/30/2006
Included observations: 1563 after adjustments
Trend assumption: Linear deterministic trend
Series: Canada Czech Republic
Lags interval (in first differences): 1 to 1

Hypothesized Trace Trace
No. of CE(s) Eigenvalue Statistic Statistic 1% CV

None 0.039689 9.73287 15.41 20.04
At most 1 0.015232 1.076477 3.76 6.65

*(**) denotes rejection of the hypothesis at the 5%(1%) level
Trace test indicates no cointegration at both 5% and 1% levels

Sample (adjusted): 10/05/2000 9/30/2006
Included observations: 1563 after adjustments
Trend assumption: Linear deterministic trend
Series: Canada Hungary
Lags interval (in first differences): 1 to 1

Hypothesized Trace Trace
No. of CE(s) Eigenvalue Statistic Statistic 1% CV

None 0.041281 10.38281 15.41 20.04
At most 1 0.013712 3.113826 3.76 6.65

*(**) denotes rejection of the hypothesis at the 5%(1%) level
Trace test indicates no cointegration at both 5% and 1% levels

Sample (adjusted): 10/05/2000 9/30/2006
Included observations: 1563 after adjustments
Trend assumption: Linear deterministic trend
Series: Canada Poland
Lags interval (in first differences): 1 to 1

Hypothesized Trace Trace
No. of CE(s) Eigenvalue Statistic Statistic 1% CV

None 0.053263 9.57937 15.41 20.04
At most 1 0.045218 1.108264 3.76 6.65

*(**) denotes rejection of the hypothesis at the 5%(1%) level
Trace test indicates no cointegration at both 5% and 1% levels

Sample (adjusted): 10/05/2000 9/30/2006
Included observations: 1563 after adjustments
Trend assumption: Linear deterministic trend
Series: UK Czech Republic
Lags interval (in first differences): 1 to 1

Hypothesized Trace Trace
No. of CE(s) Eigenvalue Statistic Statistic 1% CV

None 0.043239 12.35887 15.41 20.04
At most 1 0.013667 2.035482 3.76 6.65

*(**) denotes rejection of the hypothesis at the 5%(1%) level
Trace test indicates no cointegration at both 5% and 1% levels

Sample (adjusted): 10/05/2000 9/30/2006
Included observations: 1563 after adjustments
Trend assumption: Linear deterministic trend
Series: UK Hungary
Lags interval (in first differences): 1 to 1

Hypothesized Trace Trace
No. of CE(s) Eigenvalue Statistic Statistic 1% CV

None 0.048135 11.45927 15.41 20.04
At most 1 0.021742 2.157832 3.76 6.65

*(**) denotes rejection of the hypothesis at the 5%(1%) level
Trace test indicates no cointegration at both 5% and 1% levels

Sample (adjusted): 10/05/2000 9/30/2006
Included observations: 1563 after adjustments
Trend assumption: Linear deterministic trend
Series: UK Poland
Lags interval (in first differences): 1 to 1

Hypothesized Trace Trace
No. of CE(s) Eigenvalue Statistic Statistic 1% CV

None 0.050936 13.37259 15.41 20.04
At most 1 0.049621 1.535931 3.76 6.65

*(**) denotes rejection of the hypothesis at the 5%(1%) level
Trace test indicates no cointegration at both 5% and 1% levels

Table 6
Bilateral Johansen cointegration tests results

Sample (adjusted): 10/05/2000 9/30/2006
Included observations: 1563 after adjustments
Trend assumption: Linear deterministic trend
Series: France Czech Republic
Lags interval (in first differences): 1 to 1

Hypothesized Trace Trace
No. of CE(s) Eigenvalue Statistic Statistic 1% CV

None 0.012718 12.93341 15.41 20.04
At most 1 0.022135 1.035811 3.76 6.65

*(**) denotes rejection of the hypothesis at the 5%(1%) level
Trace test indicates no cointegration at both 5% and 1% levels

Sample (adjusted): 10/05/2000 9/30/2006
Included observations: 1563 after adjustments
Trend assumption: Linear deterministic trend
Series: France Hungary
Lags interval (in first differences): 1 to 1

Hypothesized Trace Trace
No. of CE(s) Eigenvalue Statistic Statistic 1% CV

None 0.024625 12.30229 15.41 20.04
At most 1 0.022411 1.125872 3.76 6.65

*(**) denotes rejection of the hypothesis at the 5%(1%) level
Trace test indicates no cointegration at both 5% and 1% levels

Sample (adjusted): 10/05/2000 9/30/2006
Included observations: 1563 after adjustments
Trend assumption: Linear deterministic trend
Series: France Poland
Lags interval (in first differences): 1 to 1

Hypothesized Trace Trace
No. of CE(s) Eigenvalue Statistic Statistic 1% CV

None 0.011220 13.51323 15.41 20.04
At most 1 0.000227 0.233234 3.76 6.65

*(**) denotes rejection of the hypothesis at the 5%(1%) level
Trace test indicates no cointegration at both 5% and 1% levels

Sample (adjusted): 10/05/2000 9/30/2006
Included observations: 1563 after adjustments
Trend assumption: Linear deterministic trend
Series: Germany Czech Republic
Lags interval (in first differences): 1 to 1

Hypothesized Trace Trace
No. of CE(s) Eigenvalue Statistic Statistic 1% CV

None 0.019610 12.85419 15.41 20.04
At most 1 0.010145 0.27416 3.76 6.65

*(**) denotes rejection of the hypothesis at the 5%(1%) level
Trace test indicates no cointegration at both 5% and 1% levels

Sample (adjusted): 10/05/2000 9/30/2006
Included observations: 1563 after adjustments
Trend assumption: Linear deterministic trend
Series: Germany Hungary
Lags interval (in first differences): 1 to 1

Hypothesized Trace Trace
No. of CE(s) Eigenvalue Statistic Statistic 1% CV

None 0.037715 11.68758 15.41 20.04
At most 1 0.101034 1.30381 3.76 6.65

*(**) denotes rejection of the hypothesis at the 5%(1%) level
Trace test indicates no cointegration at both 5% and 1% levels

Sample (adjusted): 10/05/2000 9/30/2006
Included observations: 1563 after adjustments
Trend assumption: Linear deterministic trend
Series: Germany Poland
Lags interval (in first differences): 1 to 1

Hypothesized Trace Trace
No. of CE(s) Eigenvalue Statistic Statistic 1% CV

None 0.009384 11.63459 15.41 20.04
At most 1 0.001731 1.004376 3.76 6.65

*(**) denotes rejection of the hypothesis at the 5%(1%) level
Trace test indicates no cointegration at both 5% and 1% levels

Sample (adjusted): 10/05/2000 9/30/2006
Included observations: 1563 after adjustments
Trend assumption: Linear deterministic trend
Series: Italy Czech Republic
Lags interval (in first differences): 1 to 1

Hypothesized Trace Trace
No. of CE(s) Eigenvalue Statistic Statistic 1% CV

None 0.001536 9.24416 15.41 20.04
At most 1 0.105125 3 .31280 3.76 6.65

*(**) denotes rejection of the hypothesis at the 5%(1%) level
Trace test indicates no cointegration at both 5% and 1% levels

Sample (adjusted): 10/05/2000 9/30/2006
Included observations: 1563 after adjustments
Trend assumption: Linear deterministic trend
Series: Italy Hungary
Lags interval (in first differences): 1 to 1

Hypothesized Trace Trace
No. of CE(s) Eigenvalue Statistic Statistic 1% CV

None 0.084951 10.30254 15.41 20.04
At most 1 0.010236 1.27428 3.76 6.65

*(**) denotes rejection of the hypothesis at the 5%(1%) level
Trace test indicates no cointegration at both 5% and 1% levels

Sample (adjusted): 10/05/2000 9/30/2006
Included observations: 1563 after adjustments
Trend assumption: Linear deterministic trend
Series: Italy Poland
Lags interval (in first differences): 1 to 1

Hypothesized Trace Trace
No. of CE(s) Eigenvalue Statistic Statistic 1% CV

None 0.02597 9.68553 15.41 20.04
At most 1 0.001273 1.37338 3.76 6.65

*(**) denotes rejection of the hypothesis at the 5%(1%) level
Trace test indicates no cointegration at both 5% and 1% levels

Table 7
Bilateral Johansen cointegration tests Results

Sample (adjusted): 10/05/2000 9/30/2006
Included observations: 1563 after adjustments
Trend assumption: Linear deterministic trend
Series: Japan Czech Republic
Lags interval (in first differences): 1 to 1

Hypothesized Trace Trace
No. of CE(s) Eigenvalue Statistic Statistic 1% CV

None 0.016365 11.43501 15.41 20.04
At most 1 0.001741 1.436223 3.76 6.65

*(**) denotes rejection of the hypothesis at the 5%(1%) level
Trace test indicates no cointegration at both 5% and 1% levels

Sample (adjusted): 10/05/2000 9/30/2006
Included observations: 1563 after adjustments
Trend assumption: Linear deterministic trend
Series: Japan Hungary
Lags interval (in first differences): 1 to 1

Hypothesized Trace Trace
No. of CE(s) Eigenvalue Statistic Statistic 1% CV

None 0.017382 11.63271 15.41 20.04
At most 1 0.741711 1.323712 3.76 6.65

*(**) denotes rejection of the hypothesis at the 5%(1%) level
Trace test indicates no cointegration at both 5% and 1% levels

Sample (adjusted): 10/05/2000 9/30/2006
Included observations: 1563 after adjustments
Trend assumption: Linear deterministic trend
Series: Japan Poland
Lags interval (in first differences): 1 to 1

Hypothesized Trace Trace
No. of CE(s) Eigenvalue Statistic Statistic 1% CV

None 0.032375 10.42683 15.41 20.04
At most 1 0.012642 2.128572 3.76 6.65

*(**) denotes rejection of the hypothesis at the 5%(1%) level
Trace test indicates no cointegration at both 5% and 1% levels