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This article was downloaded by: [129.130.252.222]On: 19 July 2014, At: 09:17Publisher: RoutledgeInforma Ltd Registered in England and Wales Registered Number: 1072954 Registered office: Mortimer House,37-41 Mortimer Street, London W1T 3JH, UK
Applied Financial EconomicsPublication details, including instructions for authors and subscription information:http://www.tandfonline.com/loi/rafe20
Extreme returns and the contagion effect between theforeign exchange and the stock market: evidence fromCyprusStelios D. Bekiros a & Dimitris A. Georgoutsos aa Department of Accounting and Finance , Athens University of Economics and Business , 76Patission Str., 104 34 Athens, GreecePublished online: 26 Nov 2007.
To cite this article: Stelios D. Bekiros & Dimitris A. Georgoutsos (2008) Extreme returns and the contagion effect betweenthe foreign exchange and the stock market: evidence from Cyprus, Applied Financial Economics, 18:3, 239-254, DOI:10.1080/09603100601018823
To link to this article: http://dx.doi.org/10.1080/09603100601018823
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Applied Financial Economics, 2008, 18, 239–254
Extreme returns and the contagion
effect between the foreign
exchange and the stock market:
evidence from Cyprus
Stelios D. Bekiros* and Dimitris A. Georgoutsos
Department of Accounting and Finance, Athens University of Economics and
Business, 76 Patission Str., 104 34 Athens, Greece
In this article we apply the Extreme Value Theory (EVT) in order to
estimate the Value-at-Risk (VaR) and the correlation of extreme returns
for two inherently unstable markets; the foreign exchange and the stock
market. We also derive the corresponding VaR estimates from more
‘traditional’ methods of estimation on daily returns of the US dollar/
Cyprus pound exchange rate and the Cyprus stock exchange general index.
The main conclusion we reach is that the more heavy-tailed distributed a
series is the more accurate the loss predictions are from the application of
the EVT. We also show that the conditional correlation index of the
extreme returns of those two markets remained almost constant through-
out the backtesting period that was characterized by ‘bear’ market
conditions.
I. Introduction
Over the last 15 years we have witnessed a massive
inflow of portfolio capital in emerging equity markets
as the result of their liberalization. It is being reported
that the average annual net private capital flow to
developing countries over the period 1983 to 1988
was $15.1 billion, whereas during the period 1989 to
1995 the figure surged to $107.6 billion. As a result of
that, the market capitalization as a proportion to
GDP rose at an unprecedented rate to over 70% in
some countries (Singh and Weisse, 1998). Among the
forces that drove advanced country flows to devel-
oping markets one could identify the lower growth
prospects in developed country stock markets, the
desire of institutional investors to diversify their
portfolios as well as the ability of foreign investors to
move funds in and out of emerging stock markets
following their external liberalization. At the same
time developing country corporations resorted to
stock market finance because the relative cost of
equity capital fell as a result of the large share price
rises during the course of 1990s’ and the large
increase of real interest rates in the aftermath of
financial deregulation.Notwithstanding those positive developments,
many empirical studies have confirmed much greater
share price volatility in emerging markets than in
more mature ones. This can be attributed to many
reasons ranging from the fact that firms in emerging
markets have not established market reputations to
the speculative nature of the portfolio capital inflows
(Tirole, 1991). The first factor explains why the share
pricing process is ‘noisy’ and the fact that only
a limited number of shares, which however account
for a considerable part of total market capitalization,
*Corresponding author. E-mail: [email protected]
Applied Financial Economics ISSN 0960–3107 print/ISSN 1466–4305 online � 2008 Taylor & Francis 239http://www.tandf.co.uk/journalsDOI: 10.1080/09603100601018823
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are actively traded. The second factor has beendocumented in many empirical studies that point tothe fact that the surge of capital towards manyemerging markets was not based on an improvementof their ‘fundamentals’. This investment strategy hasbeen rationalized from the imitative and bandwagonbehaviour of investors who endeavour to conform tothe actions of the ‘average’. This kind of behaviourhowever leads to sudden reversals of the decisionson which the capital inflows were based initially andit makes the emerging markets especially proneto internal and external shocks. Furthermore, itgenerates negative interactions between theforeign exchange and equity markets with adverserepercussions to crucial macroeconomic variables(Krugman, 1995).
The connection between the foreign exchange andthe equity market has been theoretically investigatedin the literature concerning the determinants ofexpected international asset returns. In the interna-tional version of the capital asset pricing model,developed by Solnik (1983) and Adler and Dumas(1983), the expected returns depend on a commonrisk factor which is the return on a value-weightedworld equity market portfolio, hedged againstcurrency risk. Unfortunately, the amount of currencyhedging that enters in this common factor depends onthe individuals’ utility function and relative wealth.Given the absence of information concerning thoselast issues, the model is empirically equivalent to amulti-risk factor model with a world equity marketportfolio factor and currency risk factors. Under veryrestrictive assumptions, e.g. that the purchasingpower parity holds exactly at every instant, it hasbeen shown by Grauer et al. (1976) that the worldequity market portfolio would be the sole interna-tional risk factor. The significance of the exchangerate risk as a possible determinant of asset returns hasbeen identified in a number of studies coveringvarious countries, sectors of the economy andperiods. Using cointegration analysis and errorcorrection models, Ajayi and Mougoue (1996)found evidence in favour of dynamic linkagesbetween stock prices and exchange rates for eightindustrialized countries over the period 1985 to 1991.Recently, Harvey et al. (2002) used a latent factortechnique and showed that two factors, which arerelated to the expected return on the world marketportfolio and to the foreign exchange risk, aresufficient to explain the conditional variation in theequity indices returns for 16 Organization forEconomic Coopertation and Development (OECD)countries.
The earlier discussion has highlighted the signifi-cant volatility of equity returns in emerging capital
markets, the interconnection between the equities andforeign exchange markets, especially in crises periods,and the presence of the foreign exchange risk inpricing the equities in emerging capital markets. Inthis study we attempt first, to measure the risk ofthose two markets by applying the Value-at-Risk(VaR) methodology. By definition, VaR is anestimate of the maximum expected loss on aninvestment, over a given time period, at a givenconfidence level. It turns out that VaR summarizes ina single number the downside risk of the portfolioand this explains its widespread popularity amongpractitioners and academics alike. However, VaR isnot a coherent risk measure since it does not alwayssatisfies the axiom of subadditivity according towhich diversification is beneficial to risk minimiza-tion (Artzner et al., 1999). We provide an extensivelist of VaR estimates that are based on variousmethodologies for the estimation of the SD ofreturns. Those ‘traditional’ techniques have beenextended to incorporate the Extreme Value Theory(EVT) which provides the necessary asymptotictheorems for modelling explicitly the tails of thedistribution of returns. The out-of-sample predictiveability of the various techniques has been evaluatedby means of the criterion on coverage probabilitydeveloped by Christoffersen (1998).
The issue of the contagion between the foreignexchange and the equities markets is a more delicateone since the correlation of the returns of those twomarkets might not be the appropriate measure ofdependence. It is well established now that calculatingthe correlation index on different sub-periods in orderto establish a possible breakdown between twomarkets is the wrong procedure. The reason is thatfrom a completely statistical perspective one wouldexpect higher correlations during periods of highvolatility. Boyer et al. (1999) demonstrate thatsplitting a sample of data into high and low volatilitysub-samples can yield misleading results, because sucha procedure introduces a selection bias problem whichmight suggest a correlation breakdown regardless ofwhether the coefficient has changed. Moreover, thefocus on correlation and hence on linear dependence isentirely appropriate when the joint distribution of thedata is multivariate normal or, more generally,multivariate elliptic. This of course is not the casewhen we measure the dependence at crises periods.
The structure of this article is as follows. In thenext section, we present analytically the estimationprocess of the VaR when the EVT is applied. Twoalternative techniques are applied; the POT and theBlocks Minima. The first one identifies as extremeobservations all those that exceed a pre-chosenthreshold while the second one splits the sample in
240 S. D. Bekiros and D. A. Georgoutsos
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nonoverlapping blocks and chooses the lowest returnin each one. We then proceed with the derivation ofmeasures of dependence when returns are not multi-variate normally distributed. In Section III we presentthe estimation results that have been derived fromdaily returns of the Cyprus General Index and the USdollar/Cyprus pound exchange rate. We concludeafterwards.
II. Value-at-Risk Models and ExtremalDependence: the Extreme ValueTheory Approach
Computing value-at-risk for a single position
The most critical issue in risk management is theestimation of accurate risk measures that relate to theprobabilities of having a large negative realization ofa random variable. One way to approach this issue isto employ one of the distributions that have beenadvanced in the literature for modelling high fre-quency financial returns exhibiting excess kurtosis(e.g. stable distributions, the Student-t or the ARCHprocess). One problem with this approach is that thefitted distribution might be heavily affected by thevast majority of the observations that lie in the centreof the density, whereas interest is really focused uponthe tails. One further problem is that the comparisonbetween the competing models is hampered by thefact that those models are not nested. Consequently,research has been directed into modelling the ‘tails’ ofthe distribution separately and the interest here lies inthe estimation of the so-called tail index which is agood indicator for the shape of the distribution ofextreme returns. Empirical articles by, inter alia,Blattberg and Gonedes (1974); Akgiray and Booth,(1988); Jansen and deVries (1991), attempted toanswer whether the financial series are consistentwith stable laws or equivalently whether or not thesecond moment is finite.1
In this article, we follow the second approachunder which the various methodologies by whichextreme values may be statistically modelled separateinto two forms: methods for maxima (or minima)over fixed intervals and methods for exceedances overhigh (low) thresholds. The first one is often referred
to as the Block Maxima (Minima) (BM) method and
the second one as the POT method.Under the BM method the data are divided into m
blocks with n observations in each block correspond-
ing to n trading intervals. Extremes are then defined
as the maximum (or minimum) of the n random
variables Y1,Y2, . . . ,Yn and let Zn¼
max(Y1,Y2 , . . . ,Yn) denote this maximum.2 Fisher
and Tippett (1928) have shown that for returns Yt
that are independent and drawn from the same
distribution F, if there exist normalizing constants wn
and qn such that
limn!1
PZn � wn
qn � y
� �¼ lim
n!1Fnðqnyþ wnÞ ¼ HðyÞ ð1Þ
for some nondegenerate limit distribution H, then H
belongs to three families of distributions which
according to Jenkinson (1955) can be represented
by the Generalized Extreme Value distribution
(GEV), i.e.
HðyÞ ¼expð�ð1þ �yÞ�1=�
Þ if � 6¼ 0
expð�e�yÞ if � ¼ 0
( ),
ðy, �Þ 2 R, ð1þ �yÞ � 0 ð2Þ
According to the tail index value, �, three types of
extreme value distributions are distinguished: the
Frechet distribution (�>0), the Weibull distribution
(�<0) and the Gumbel distribution (�¼ 0). It follows
therefore that, whatever the distribution of the
original random variables the limiting distribution
of the maximum has a small set of possible
distributions. If (1) holds, we shall say that F belongs
to the maximum domain of attraction of H and write
F2MDA(H�). Essentially all the common, contin-
uous distributions of statistics are in MDA(H�) for
some value of �. Thus the normal, lognormal,
exponential and gamma distributions correspond to
the Gumbel case. The heavy tailed distributions
typically encountered in finance are in the Frechet
domain of attraction.3 This class includes the Pareto,
Cauchy Student-t and mixture distributions.We do not know the underlying distribution of
financial returns but since there is a growing
consensus that they have heavy tails the Frechet
limit will be the relevant case. In accordance to the
theorem presented above we fit the GEV distribution
1The tail probabilities of stable distributions approximate those of the Pareto distribution. Therefore, the tail index of thePareto distribution that is fitted on the extremes conveys information on the shape of the entire density function, (Campbellet al., 1997).2 In the text we present the theoretical results for the maximum only. However, the results for the mimimum are identicalsince: max(Y1,Y2, . . . ,Yn)¼�min(�Y1,�Y2 , . . . ,Yn), (Longin, 2000).3De Haan (1976) has derived the necessary conditions for the moments to exist when the underlying distributionF2MDA(H�). For a heavy tailed distribution �>0 the kth moment does not exist if k� (1/�).
Extreme returns and the contagion effect between the FE and the stock market 241
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H�,�,�¼H[(Zn��)/�)] on the standardized data ofblock minima, (Zn��)/�. The location parameter �and the positive scale parameter � take care of theunknown sequences of normalizing constants wn andqn. Let us now define with Rn,k a level that we expectto be exceeded, on average, in one n-block for every kn-blocks. If we believe that maxima in blocks oflength n follow the generalized extreme valuedistribution, the Rn,k is a quantile of this distribution,that is a VaR estimate, and from (2) we can derive
Rn,k ¼H�1�,�,�
1�1
k
� �¼�
_��_
�_
1� � log1�1
k
� �� ���_
0@
1A
ð3Þ
where �, � and � have been substituted for theirmaximum likelihood estimates. If returns Yi areindependent then the following holds:
1� 1
k
� �¼ PðY1 � Rn, k, . . . ,Yn � Rn, kÞ ¼ FnðRn, kÞ
ð4Þ
so the (1� 1/k) quantile, Rn,k, for the distribution ofZn corresponds to the (1� 1/k)1/n quantile of themarginal distribution of Yi (Longin, 2000). Supposefor example that we consider our model for annual(261 days) maxima. Then, the return that we expect tobe exceeded once every 20 years, the 20-year returnlevel, corresponds to the (0.95)(1/261)¼ 0.9998 quantile.
The results we presented above have been derivedfor the case of stationary, identically and indepen-dently (i.i.d.) distributed random variables. InLeadbetter et al. (1983) we find two technicalconditions under which the extreme value theoremsextend to conditional processes. The first conditionrequires that the extremes of a process are weaklydependent only in the long run (Longin (2000) for acondition of the degree of dependence that must besatisfied). Considering that the dependence in returnsstems from different volatility regimes that changewith time, it is not unreasonable to assume that in thelong run extreme returns are effectively independent.The second condition requires that no clusters ofextreme values appear. However, since the financialtime series show clusters of volatility that lead toclusters of large values the second condition isunrealistic and we must look more carefully into theissue of de-clustering the extreme values so that theyappear as approximately independent (McNeil,1998). Let (Yn) be a stationary variable with marginaldistribution F, where Zn¼max(Y1 , . . .,Yn) and ð ~YnÞ
an associated independent process with the same
marginal distribution F where ~Zn ¼ maxð ~Y1, . . . , ~YnÞ.
The extremal index, for large n, is defined as a real
number 0� �� 1 such that:
PfZn � Rn, kg � P�f ~Zn � Rn, kg ¼ Fn�ðRn, kÞ ð5Þ
Under this definition the maximum of n observations
from the noni.i.d. series behaves like the maximum of
n� observations from the associated i.i.d. variable.
It can be also shown that the maxima Zn of a noni.i.d.
series converge in probability to H�(Y) and from
Equation 3 that the VAR estimate is given by
Rn, k ¼ Y1=n�ð1�1=kÞ (McNeil, 1998; Longin, 2000).
A natural asymptotic estimator of � is:
� ¼ n�1 �ln 1� Ku=mð Þ
ln 1�Nu=ðm � nÞð Þð6Þ
where Nu is the number of exceedances of the
threshold u, Ku is the number of blocks the threshold
is exceeded and m, n, stand for the number of blocks
and days in each block respectively, (Smith and
Weissman, 1994). The asymptotic derivation of the
previous equation suggests that we should attempt to
keep both m and n large (McNeil, 1998).Under the Peaks over Threshold, POT, method we
fix a high threshold u and look at all exceedances y
over u. If F(Y) represents the distribution function of
returns Y, then the cumulative distribution of the
u-xceedances, denoted by Fu(y), is defined by:
FuðyÞ ¼ P Y � yþ u Y> uj½ � ¼Fðyþ uÞ �FðuÞ
1�FðuÞ, x> 0
ð7Þ
where 0� y< x0� u and x0�1 is the (finite or
infinite) right endpoint of F. Balkema–de Haan
(1974) and Pickands (1975), studied the asymptotic
behaviour of threshold exceedances and proved for a
large class of the underlying distribution Fu(y) that its
limiting distribution, as the threshold is raised, is the
Generalized Pareto Distribution (GPD) which is
given by:
GðyÞ ¼ 1�1þ �y
�
� ��1=�
, � 6¼ 0
GðyÞ ¼ 1� expð�yÞ, � ¼ 0
ð8Þ
where � is the tail index, �>0 the scale parameter
and the support is y� 0 when �>0 and 0< y<
�(�/�) when �<0.4 Essentially all the common
continuous distributions of statistics belong in this
class of distributions. For example the case �>0
4An extremal index, which measures the degree of clustering of extremes above the threshold, can be obtained in this methodas well by using the runs estimator (Smith and Weissman, 1994).
242 S. D. Bekiros and D. A. Georgoutsos
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corresponds to heavy tailed distributions such as thePareto and Student-t. The case �¼ 0 corresponds todistributions like the normal or the lognormal whosetails decay exponentially. The short-tailed distribu-tions with a finite endpoint such as the uniform orbeta correspond to the case �<0.
We now discuss how the results of the last sectioncan be used to estimate VaRs. Let yi
� �Nu
i¼1be the
sample of exceedances of a high threshold, u, with itssize being Nu. If we assume that those Nu excessesare i.i.d. with an exact GPD distribution then themaximum likelihood estimates of the GPD param-eters � and � are consistent and asymptoticallynormal as Nu!1 provided that �>�1/2 (Smith,1987). We define �FuðyÞ ¼ 1� FuðyÞ and then byemploying the identity shown in (7) we have:
�Fðuþ yÞ ¼ �FðuÞ �FuðyÞ ð9Þ
In (7) we substitute �Fðuþ yÞ ¼ 1� p, the confidencelevel, �FðuÞ ¼ Nu=n, the proportion of the data in thetail and FuðVaRð1� pÞ � uÞ ¼ GðVaRð1� pÞ � uÞwhere G represents the GPD with the parameters �and � substituted for the maximumlikelihood estimates. From (9) then we can estimatep-quantiles as:
VaRð1� pÞ ¼ uþ�
�
nð1� pÞ
Nu
� ���
�1
( )ð10Þ
Measuring extreme value dependence
Estimating dependence between risky asset returnsis of paramount importance in risk management.Unfortunately, the conventional measure of depen-dence, the correlation index, is appropriate only whenthe assumption of multivariate normally distributedreturns is tenable. Correlation is a measure of thelinear association between two variables since byconstruction it assigns the same weights on alldeviations from the mean. There are cases howeverwhere the extreme realizations have a dependencestructure that is different from the rest of the sample.More formally, it has been shown that a class ofmultivariate distributions where the standard correla-tion approach to dependence is natural and unprob-lematic is the elliptical distributions. The ellipticaldistributions, of which the multivariate normal is aspecial case, are distributions whose density isconstant on ellipsoids. In two dimensions, thecontour lines of the density surface are ellipses.Interestingly, a multivariate distribution with uncor-related components is not a distribution with
independent components. It provides an example
where zero correlation of risks does not imply
independence of risks. Only in the case of the
multivariate normal can the lack of correlation be
interpreted as independence.Copulas, or dependence functions, represent a way
of trying to extract the dependence structure from the
joint distribution. This is being accomplished by
separating the joint distribution into a part that
describes the dependence structure and a part that
describes the marginal behaviour only. Let us
consider a q-dimensional vector of random returns
denoted by Y0 ¼ (Y1,Y2, . . . ,Yq)0 with marginal dis-
tributions F1, . . . ,Fq. The joint distribution function
C of (F1(Y1), . . . ,Fq(Yq))0 is then called the copula of
the random vector Y0 ¼ (Y1,Y2, . . . ,Yq)0. It follows
then that:
Fðy�1, . . . , y�qÞ ¼ Prob½Y1 � y�1, . . . ,Yq � y�q�
¼ CðF1ðy�1Þ, . . . ,Fqðy
�qÞÞ ð11Þ
where y�i ¼ ui þ yi and yi refers to the exceedance of
Yi over the threshold ui. Moreover, Sklar (1959)
proved that F has a unique copula if the marginal
distributions are continuous. However, if there are
discontinuities in one or more marginals then there is
more than one copula representation for F. In either
case, it makes sense to interpret C as the dependence
structure of F. As with rank correlation, the copula
remains invariant under (strictly) increasing transfor-
mations of the risks; the marginal distributions
clearly change but the copula remains the same.Once the problem is to study the dependence
structure of extreme returns, the multivariate return
exceedances distribution must be defined. As with the
univariate case the exact distribution is not exactly
known and therefore we have to consider asymptotic
results. The possible limit nondegenerate distribution
however must satisfy two properties; first, that the
marginal distributions are generalized Pareto distri-
butions and second that the correlation increases at
high confidence intervals. The two properties take
care of the fat-tails feature of univariate returns and
of the empirical regularity of correlations increases at
crisis periods. The second property is satisfied by the
logistic model in the bivariate extreme value family
that is given by:
Cðs, tÞ ¼ PrðS � s, T � tÞ
¼ exp � s�ð1=aÞ þ t�ð1=aÞ� �ah i
, 0 < a � 1
ð12Þ
(Tawn, 1988; Longin and Solnik, 2001). In order to
dissociate the correlation structure from the marginal
Extreme returns and the contagion effect between the FE and the stock market 243
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distributions the bivariate return exceedances havebeen transformed to unit Frechet margins,S ¼ �1= logFu1 ðy1Þ, T ¼ �1= logFuu ðy2Þ, whereFui ðyiÞ is the GPD of exceedance yi. The asymptoticdependence of (S,T) is defined by:
� ¼ lims!1
PrT � s
S � s
� �ð13Þ
where 0��� 1, and the two variables are termedasymptotically dependent if �� 0 and asymptoticallyindependent if �¼ 0. The relationship between thecoefficient �, of Equation 12 and � is given by�¼ 2� 2� so when the variables are exactly indepen-dent �¼ 1 and �¼ 1 while when � 1 the variables areasymptotically dependent to a degree depending on �.
Since we have chosen the two thresholds, thebivariate distribution of return exceedances is thendescribed by seven parameters: the two tail probabil-ities, the dispersion parameters and the tail indexes ofeach variable, and the dependence parameter of thelogistic function. The parameters of the model areestimated by the maximum likelihood method. In thebivariate case, the correlation coefficient of extremesis related to the coefficient of dependence by�¼ 1� �2 (Tiago de Oliveira, 1973).
III. Empirical Evidence
We implement the various VaR estimation techniqueson daily returns of the US dollar/Cyprus poundexchange rate and the Cyprus Stock Exchangegeneral index (CGI). The series cover the period 1April 1996 to 27 April 2001.5 Both series have beentested for the null hypothesis of being normal and thishas been rejected under both the Kolmogorov–Smirnov test statistic and the �2 test for normality.The period 30 April 2001 to 19 April 2002 has beenreserved for backtesting the predictive performanceof the alternative models. Our first goal is to validatethe adequacy of competing VaR methodologiesthrough the backtesting exercise. On the one handwe examine ‘conventional’ models that encompassboth parametric and simulating techniques and onthe other hand the two approaches offered by the
Extreme Value Theory. The parametric models havebeen estimated under various specifications of theconditional distribution of the error generatingprocess that is the Gaussian (N), the student (t) andthe Generalized Error Distribution (GED).Moreover, each one of those models has beenestimated under various specifications for the condi-tional variance process which is alternatively approxi-mated by a Moving Average process, theExponentially Weighted Moving Average (EWMA)specification and the GARCH(1,1) model. The samethree specifications of the conditional variance areemployed with the Monte Carlo simulation method.A more detailed presentation of these techniques isgiven in appendix A.
For the Blocks method we analysed monthly andquarterly minima and the fit of the Frechet distribu-tion on both sets of sample minima was found to beadequate. For each block maximum (minimum) thecorresponding crude residual is defined to be:
Wi ¼ 1þ�
�
� �ðZi � �Þ
� ��ð1=�Þ
ð14Þ
According to Cox and Snell (1968) these should bei.i.d. unit exponentially distributed and this hypoth-esis can be checked using graphical diagnostics suchas the QQ-plots (quantile–quantile plots) of theexponential distribution against the residuals ofthe fitted model (Figs 1 and 2). If the sample is arealization from the reference distribution, the QQplot must be approximately linear. A concave(convex) departure from linearity is an indication ofa heavier (thinner) tail than the reference distribu-tion.6 The obtained evidence suggests that theexponential distribution provides an adequate fit tothe residuals of Equation 14 which however is notvalidated from more formal testing procedures likethe Kolmogorov–Smirnov statistic due to the limitednumber of extreme values generated by the Blockmethod.
In order to interpret correctly the evidence on thereturn level Rn,k, that is exceeded in one n-block outof every k, we should know the estimate of theextremal index, �. This is the case because if the seriestends to form clusters then we may know thefrequency of stress periods, i.e. the periods when we
5The Cyprus pound had been pegged to ecu and from January 1999 to euro with fluctuation margins 2.25%. From 1January 2001, wider bands of 15% were introduced. This exchange rate policy meant that the Cyprus pound was effectivelyfloating against the US dollar. The Cyprus Stock exchange started operating on 29 March 1996 and its performance can bedivided into three periods. The first period, till 30 June 1999, was characterized by low volatility, low volumes and persistenceof the General index around the initial level of 100. The second period, up to 31 October 2000, had all the features of a bubblethat burst after 1.5 years. During the ensuing period the General index returned to its initial levels but with a higher volatilitythan the first period (Nerouppos et al., 2002).6 If the empirical and the reference distributions are of the same forms, but with different location parameters, the QQ plot isstill linear but with an intercept different than zero (Gencay and Selcuk, 2004).
244 S. D. Bekiros and D. A. Georgoutsos
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experience an exceedance of the VaR level Rn,k, butwe do not know how many of them occur in eachparticular n-block. We have estimated, fromEquation 6, the extremal index � using monthly andquarterly blocks and the estimated values arereported in Table 1. They have been estimated forvarious thresholds that are exceeded by between 15and 150 observations (McNeil, 1998). For example,we observe that with quarterly blocks, in the foreignexchange, FX, case the � estimates range between0.18 and 0.49 and thus we consider the quarter-� to betheir average value of 0.35. Based on this averageestimate we can derive a value for the average clustersize (1/�) of about 2.85 extreme observations per eachquarter. Another interesting observation is that theconcentration of extremes is similar in the stock andthe FX markets.
The estimated parameters of the GEV distribution,the calculated quantiles at various confidence levelsas well as their respective confidence intervals (95%)
are reported in Table 2. For example, the estimated� parameters for the CGI index are 0.73 and 0.29 formonthly and quarterly minima respectively. On thebasis of the evidence provided by the estimated 95%confidence intervals we cannot reject the hypothesis(�<0) of a thin-tailed marginal distribution for theFX rate case, at the 95% level for the quarterlyfrequency. However, we can do so for the CGI caseon the monthly frequency. The calculated VaRs fromEquations 3 and 5 admit the following interpretation.Based on the average estimate of � in Table 1 we candeduce, e.g. that the VaR¼�4.33% estimate for theCGI at the 98% level, with monthly blocks, will beexceeded once every four months. The estimates forthe FX rate case are less satisfactory since theconfidence intervals of the tail index, �, includenegative values that are statistically compatible withthinly-tailed distributed extreme returns although thepoint estimates indicate a heavy tailed distribution.With respect to the VaR estimates we note that theyare considerably smaller when compared to theircounterparts of the CGI index. This is what weexpected considering the substantially higher volati-lity of the Cyprus stock exchange over the period weexamined.
In order to estimate the threshold, u, for the POTmethod we follow Neftci (2000) according to whomu¼ 1.176�n, with �n the SD of ðYtÞ
nt¼1 and
1:176 ¼ F�1t ð0:10Þ ¼ 1:44
ffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffið�� 2Þ=�
pwhen a
Student-t (�¼ 6) distribution F, is being assumed.This implies that the excesses over the thresholdbelong to the 10% tails and in our case they havebeen estimated to be 0.012 and 0.01 (in absolutevalues) for the returns of the FX rate and the CGIindex respectively. The choice of the optimal thresh-old is a delicate issue since it is confronted with abias-variance tradeoff. If we choose too low athreshold we might get biased estimates because thelimit theorems do not apply any more while highthresholds generate estimates with high SE due to thelimited number of observations.
An alternative procedure to determine the appro-priate threshold would be to use the plot ofthe sample mean excess function (MEF) that isdefined by:
snðuÞ ¼
Pni¼1 ðYi � uÞþPni¼1 1 Yi>uf g
ð15Þ
This function expresses the sum of the excesses overthe threshold, u, divided by the number of data pointsthat exceed it. Based on the picture of the MEF, if itexhibits an upward trend we can infer a heavy tailedbehaviour for the data whereas a short taileddistribution would show a downward trend and
00
Ordered data
Exp
onen
tial q
uant
iles
1
1
2
2
3
3
Fig. 2. QQ-plot of residuals from the fitted GEV (1 April
1996 to 27 April 2001) on quarterly block minima against the
exponential distribution (USD/CYP) (Equation 14)
0.0 1.0 2.0 2.5 3.0
0
2
Ordered data
Exp
onen
tial q
uant
iles
0.5 1.5
1
3
Fig. 1. QQ-plot of residuals from the fitted GEV (1 April
1996 to 27 April 2001) on quarterly block minima against the
exponential distribution (CGI)
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Table 2. VaR estimates on 30 April 2001 – in absolute values – and their 95% confidence intervals for the CYP/USD rate
and the CGI (1 April 1996 to 27 April 2001). Method of estimation: Block Minima (Equations 3 and 5)
Variables Month Quarter
CYP/USDn 20 60m 66 22� 0.0296 (�0.1713, 0.2305) 0.0219 (�0.402, 0.446)� 0.0035 (0.00271, 0.00428) 0.0040 (0.00243, 0.00557)� 0.0106 (0.00962, 0.01158) 0.0134 (0.01124, 0.0155)Rn,k (VaR 95%) K¼ 2 K¼ 1
VaR¼ 1.12% VaR¼ 1.08%Rn,k (VaR 96%) K¼ 2 K¼ 1
VaR¼ 1.19% VaR¼ 1.17%Rn,k (VaR 97%) K¼ 2 K¼ 1
VaR¼ 1.30% VaR¼ 1.28%Rn,k (VaR 98%) K¼ 3 K¼ 2
VaR¼ 1.44% VaR¼ 1.45%Rn,k (VaR 99%) K¼ 6 K¼ 3
VaR¼ 1.70% VaR¼ 1.73%Rn,k (VaR 99.5%) K¼ 12 K¼ 6
VaR¼ 1.95% VaR¼ 2.01%Rn,k (VaR 99.9%) K¼ 60 K¼ 27
VaR¼ 2.57% VaR¼ 2.69%Rn,k (VaR 99.95%) K¼ 120 K¼ 53
VaR¼ 2.84% VaR¼ 2.99%Rn,k (VaR 99.99%) K¼ 596 K¼ 263
VaR¼ 3.49% VaR¼ 3.70%
CGIn 20 60m 66 22� 0.7328 (0.135, 1.33) 0.2912 (�0.3795, 0.9619)� 0.0119 (0.0064, 0.0173) 0.0191 (0.0098, 0.0283)� 0.0167 (0.0116, 0.0327) 0.0260 (0.0152, 0.0367)Rn,k (VaR 95%) K¼ 2 K¼ 2
VaR¼ 2.21% VaR¼ 2.63%Rn,k (VaR 96%) K¼ 2 K¼ 2
VaR¼ 2.61% VaR¼ 3.09%Rn,k (VaR 97%) K¼ 3 K¼ 2
VaR¼ 3.22% VaR¼ 3.71%Rn,k (VaR 98%) K¼ 4 K¼ 3
(continued)
Table 1. Estimates of the extremal index, � for the CYP/USD exchange rate and the CGI index (1 April 1996 to 27 April 2001),
(Equation 6)
(m, n) Nu 15 20 25 30 40 50 100 150 Average �
CYP/USD(55, 20) Ku 12 15 19 23 25 29 43 51Month � 0.76 0.75 0.76 0.77 0.64 0.58 0.43 0.33 0.63(18, 60) Ku 8 9 11 12 13 14 16 –Quarter � 0.49 0.45 0.44 0.40 0.28 0.25 0.18 – 0.35
CGI(66, 20) Ku 11 12 13 15 16 18 23 31Month � 0.92 0.68 0.62 0.69 0.48 0.45 0.32 0.27 0.55(22, 60) Ku 8 9 10 11 12 13 15 19Quarter � 0.70 0.54 0.52 0.49 0.41 0.45 0.23 0.20 0.44
Notation: m, n stand for the number of blocks and days in each block respectively.Nu, Ku, stand for the number of exceedances of the threshold u and the number of blocks this threshold has been exceeded.
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exponentially distributed data would give an approxi-mately horizontal line. If the empirical plot appearsto follow a reasonably straight line with a positivegradient, then this is an indication that the datafollow a GPD with a positive shape parameter � inthe tail area above u (Embrechts et al., 1997). Theplots of the MEF, above the thresholds estimated bythe Neftci procedure, suggest that the exponentialfunction perhaps would suit the FX returns data set(Fig. 3) while the GPD might provide a reasonable fitto the CGI (Fig. 4). Hereafter, we apply the GPD toboth cases and check its appropriateness by its overallfit in the tail area (Figs 5 and 6).
The absolute values of the (negative) daily returnsof the FX rate and the CGI that exceed the chosenthresholds have been used to estimate the GPD(Equation 8) where the pth quantile VaR is beingcalculated from Equation 10. The crucial parameter isthe tail index, �, where in general terms the higher itsvalue, the heavier the tail and the higher the quantileestimates we derive. Consequently, we have derived
VaR estimates corresponding to eight different levelsof significance (95%, 96%, 97%, 98%, 99%, 99.5%,99.9% 99.95%, 99.99%). The results on 30 April2001 are presented in Table 3, alongside those of thecompeting methods, and the main picture that
Table 2. Continued
Variables Month Quarter
VaR¼ 4.33% VaR¼ 4.69%Rn,k (VaR 99%) K¼ 8 K¼ 6
VaR¼ 7.2% VaR¼ 6.63%Rn,k (VaR 99.5%) K¼ 16 K¼ 11
VaR¼ 11.95% VaR¼ 9.01%Rn,k (VaR 99.9%) K¼ 76 K¼ 53
VaR¼ 38.8% VaR¼ 16.76%Rn,k (VaR 99.95%) K¼ 152 K¼ 105
VaR¼ 64.5% VaR¼ 21.4%Rn,k (VaR 99.99%) K¼ 760 K¼ 522
VaR¼ 209.7% VaR¼ 36.55%
Notation: n and m stand for the number of days in each block and the number of blocks in our samplerespectively.K refers to the number of blocks that the estimated VaR will be exceeded.
0.0 0.02 0.04 0.06 0.08
0.010
0.015
0.020
0.025
Threshold
Mea
n ex
cess
Fig. 3. Sample mean excess function for the CGI index
(1 April 1996 to 27 April 2001), (Equation 15)
0.0 0.005 0.010 0.015 0.0200.0030
0.0035
0.0040
0.0045
0.0050
Threshold
Mea
n ex
cess
Fig. 4. Sample mean excess function for USD/CYP (1 April
1996 to 27 April 2001), Equation 15
0.05 0.10
0.0
0.2
0.4
0.6
0.8
1.0
y (log scale)
Fu(
y–u)
Fig. 5. Fit of the estimated Generalized Pareto function for
CGI (1 April 1996 to 27 April 2001)
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emerges is that the estimated VaRs were substantiallyhigher for the CGI returns due the higher estimatedvalue of �. We found the maximum likelihood pointestimates of � to be equal to �0.0367 for the CYP/USD rate and 0.2178 for the CGI returns while the95% confidence intervals could not exclude positivevalues for the former variable whereas the same couldnot be claimed for negative values of the latter one.7
Figures 5 and 6 depict the fit of the estimated GPDfunction for the CGI and the FX rate cases,respectively. Although the evidence from the sampleMEF suggested that we might not have beensuccessful in fitting the GPD on the FX data set,the fit of this distribution on the exceedences seemsreasonable to the naked eye. This fit is furtherinvestigated by using the crude residuals:
Wi ¼1
�log 1� �
ðYi � uÞþ
� þ �ðu� �Þ
� �ð16Þ
as defined by McNeil and Saladin (2000). Theseshould be i.i.d. unit exponentially distributed and thishypothesis can be checked by using, among othertechniques, the QQ plots of the quantiles of theexponential distribution against those of the empiricalone. Figures 7 and 8 present the diagrams for the twocases and it appears that the excesses over thethreshold are adequately modeled by the GPDfunctions since the points lie approximately along astraight line. This evidence is further supported fromthe application of the Kolmogorov–Smirnov teststatistic under which the null hypothesis that theresiduals in (16) are i.i.d. unit exponentially distributedcannot be rejected at the 1% level (the values of the teststatistics are 0.045 and 0.048 for the CGI and the FXseries respectively when the 1% critical value is 0.049).
The VaR estimates, on 30 April 2001, for all the
methods implemented, including the EVT ones, are
presented in Table 3 whereas their out-of-sample
performance is evaluated in Table 4. This evaluation is
based on one-step-ahead forecasts that have been
produced from a series of rolling samples with a size
equal to that of the initial sample (1 April 1996–
27 April 2001). Figures 9 and 10 offer a visual
presentation of the estimated VaRs (99%) with three
representative models; the GARCH(1,1), the Risk
Metrices (RM) (0.94) and the Blocks Maxima with
quarterly blocks. The main features that are worth
mentioning are that the extreme value estimates are
generally higher and they are considerably less volatile
than the other two. The rolling samples do not
generate substantial change of the data set of extreme
observations and as a result the EVT VaR estimates
are almost time independent. On the other hand, in the
GARCH–type models variances are forecasted by an
exponential model with declining weights on past
observations and therefore are crucially dependent on
the last observation that is added in the sample. The
policy suggestion of the above evidence is that the
EVT models are more suitable for long-run forecasts
of the ‘maximum’ potential losses rather than being a
day-to-day tool to measure the market risk.Various methods and tests have been suggested for
evaluating VaR model accuracy. In this article we
implement Christoffersen’s (1998) likelihood ratio
tests for coverage probability. The first one tests
whether the probability of the unconditional coverage
failure, a*, is equal to the level a selected for the VaR
calculation. Thus, the relevant null hypothesis is N0:
a*¼ a against the alternative N0: a* 6¼ a. As the
number of exceptions, x, follows a binomial distribu-
tion the likelihood ratio test statistic is:
LRuc ¼ �2 ln½ð1� aÞn�xax�
þ 2 ln½ð1� a�Þn�xða�Þx� �!
d�2ð1Þ ð17Þ
where the maximum likelihood estimator of a* is (x/n).
The second test checks whether deviations are time
dependent and the null hypothesis is that the prob-
ability of an exception occurring is independent on
what happened the day before. LRind tests for the serial
independence of the exceptions and it is defined as:
LRind ¼ �2 ln ð1� a�ÞðT00þT10Þða�ÞðT01þT11Þ �
þ 2 ln 1� a0ÞT00aT01
0 ð1� a1ÞT10aT11
1
��!d
�2ð1Þ
ð18Þ
0.009 0.020 0.030 0.040
0.0
0.2
0.4
0.6
0.8
1.0
y (log scale)
Fu(
y–u)
Fig. 6. Fit of the estimated GPD for USD/CYP (1 April
1996 to 27 April 2001)
7 The estimated values of the shape parameter � obtained from the POT and BM methods are very similar. Both indicate thatextremes from the FX rate variable could equally well be modeled by a thin-tailed distribution while the confidence intervalsfrom both models overlap.
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Tij measures the number of days in which state joccurred while it was at i the day before and ajdenotes the probability of observing an exceptionconditional on state j the previous day. If we assign
the indicators (i, j) to 0 if VaR is not exceeded and to1 otherwise then the maximum likelihood estimates ofa0 and a1 are given by (T01/(T00þT01)) and(T11/(T10þT11)) respectively. Thus, if the occurrence
Table 3. VaR (%) estimates – in absolute values – on 30 April 2001. Various methods of estimation
Percentage 95% 96% 97% 98% 99% 99.5% 99.9% 99.95% 99.99%
CYP/USDRM(0.94) 1.48 1.58 1.70 1.85 2.10 2.32 2.79 2.97 3.35MA(20) 1.49 1.58 1.70 1.86 2.11 2.33 2.80 2.98 3.37MA(60) 1.58 1.69 1.81 1.98 2.24 2.48 2.98 3.17 3.58GARCH(GED) 1.56 1.66 1.78 1.94 2.20 2.44 2.93 3.12 3.52GARCH(N) 1.58 1.69 1.81 1.98 2.24 2.48 2.98 3.17 3.58GARCH(t) 1.57 1.67 1.80 1.96 2.22 2.46 2.95 3.14 3.55HS 1.14 1.22 1.30 1.41 1.61 1.88 2.53 2.60 2.66MC-RM(0.94) 1.47 1.62 1.73 1.90 2.15 2.29 2.90 2.97 3.03MC-MA(60) 1.61 1.67 1.79 1.97 2.09 2.22 2.48 2.49 2.49MC-GARCH(GED) 1.54 1.58 1.69 1.90 2.25 2.48 2.57 2.74 2.87MC-GARCH(N) 1.52 1.68 1.79 1.96 2.16 2.32 2.75 2.92 3.05MC-GARCH(t) 1.51 1.59 1.77 1.92 2.19 2.52 3.11 3.31 3.48EVT-POT 1.13 1.21 1.31 1.45 1.69 1.92 2.43 2.64 3.11EVT-BM(60) 1.08 1.17 1.28 1.45 1.73 2.01 2.69 2.99 3.70
CGIRM(0.94) 2.85 3.03 3.25 3.55 4.03 4.46 5.35 5.69 6.44MA(20) 2.65 2.82 3.03 3.31 3.75 4.16 4.98 5.31 6.00MA(60) 2.85 3.04 3.26 3.56 4.03 4.47 5.36 5.71 6.45GARCH(GED) 3.36 3.57 3.84 4.19 4.75 5.26 6.31 6.72 7.59GARCH(N) 3.29 3.50 3.76 4.10 4.65 5.15 6.18 6.58 7.43GARCH(t) 3.40 3.62 3.89 4.25 4.81 5.33 6.39 6.80 7.69HS 2.39 2.69 3.02 3.65 4.96 6.34 9.56 9.94 10.05MC-RM(0.94) 2.92 3.07 3.28 3.78 4.18 4.41 5.10 5.94 6.62MC-MA(60) 2.85 3.06 3.30 3.55 3.94 4.46 4.63 4.69 4.74MC-GARCH(GED) 3.13 3.36 3.56 4.00 4.42 4.79 5.48 5.85 6.15MC-GARCH(N) 3.32 3.44 3.70 3.92 4.29 4.73 5.32 5.75 6.10MC-GARCH(t) 3.42 3.58 3.85 4.17 4.56 5.31 6.70 6.82 6.92EVT-POT 2.38 2.69 3.11 3.73 4.89 6.18 9.79 11.66 16.87EVT-BM(60) 2.63 3.09 3.71 4.69 6.63 9.01 16.76 21.4 36.55
Notation: RM¼Riskmetrics, MA(60)¼ 60 days moving average, GED¼Generalized Error Distribution, MC¼Monte-Carlo, HS¼Historical Simulation, POT¼Peaks-over-Threshold, BM(60)¼ 60 days blocks.
0 2 4
0
1
2
3
4
5
Ordered quantiles
Exp
onen
tial q
uant
iles
1 3 5
Fig. 8. QQ Plot of residuals from the fitted GPD (1 April
1996 to 27 April 2001) against the exponential distribution
(USD/CYP), (Equation 16)
0 2 4
0
1
2
3
4
5
Ordered quantiles
Exp
onen
tial q
uant
iles
1 3
Fig. 7. QQ Plot of residuals from the fitted GPD (1 April
1996 to 27 April 2001) against the exponential distribution
(CGI), (Equation 16)
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Table 4. Number of exceedances, F, and 95% LRuc nonrejection test confidence regions (Equation 17). Backtesting sample
period: 30 April 2001 to 19 April 2002 (255 observations)
Percentage 95% 96% 97% 98% 99% 99.5% 99.9% 99.95% 99.99%
Failures (LRuc) 6<F<21 4<F<17 2<F<14 1<F<11 F<7 F<5 F<2 F<2 F<1
CYP/USDRM(0.94) 14 11 9 6 5 4 2 2 1MA(20) 14 12 9 7 4 4 2 2 1MA(60) 15 11 7 5 4 3 2 1 0GARCH(GED) 15 13 8 5 4 3 2 1 0GARCH(N) 15 13 7 5 4 3 2 1 0GARCH(t) 15 13 7 5 4 3 2 1 0HS 23 20 18 13 7 3 1 1 1MC-RM(0.94) 14 13 9 7 5 4 3 3 2MC-MA(60) 16 12 8 5 5 4 2 2 2MC-GARCH(GED) 16 13 9 5 4 3 2 2 2MC-GARCH(N) 16 12 10 5 4 2 1 1 1MC-GARCH(t) 16 15 10 6 4 4 2 1 1EVT-POT 23 21 17 12 6 3 1 1 1EVT-BM(60) 24 23 22 15 5 3 1 1 1
CGIRM(0.94) 19 12 11 9 4 2 1 1 1MA(20) 22 18 16 11 5 3 2 2 2MA(60) 12 9 9 8 5 3 2 2 1GARCH(GED) 22 19 14 13 8 7 4 4 1GARCH(N) 19 13 9 8 6 5 2 1 1GARCH(t) 22 19 14 13 9 7 4 4 1HS 18 14 11 5 3 2 0 0 0MC-RM(0.94) 17 12 11 9 5 4 1 1 1MC-MA(60) 11 10 10 9 5 4 2 2 1MC-GARCH(GED) 24 18 16 13 9 7 5 3 3MC-GARCH(N) 19 14 9 8 6 5 4 2 2MC-GARCH(t) 21 18 18 12 10 7 5 5 1EVT-POT 15 13 9 4 3 2 0 0 0EVT-BM(60) 17 10 6 3 2 1 0 0 0
Notes: Numbers in italics indicate, statistically significant, overestimation or underestimation of risk. F is the number offailures that could be observed without rejecting the null that the models are correctly calibrated at the 95% level ofconfidence.
−0.06
−0.04
−0.02
0
0.02
0.04
0.06
0.08
0.1
0.12
0.14
1 51 101 151 201 251
Returns GARCH(1,1) RM(0.94) EVT-BM(60)
Fig. 9. CGI returns, negated and VaR (99%) estimates (30 April 2001 to 19 April 2002)
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of an exception is independent of previous day’s
conditions then a¼ a0¼ a1¼ (T01þT11)/T) and LRind
should not be statistically significant. By combining
the two tests, a third test of conditional coverage,
LRcc, can be constructed as:
LRcc ¼ LRuc þ LRind �!d
�2ð2Þ ð19Þ
In Table 4 we present the number of exceedances as
well as the confidence regions of failures that are
implied from Christoffersen’s (1998) likelihood ratio
tests. The main evidence is that for the FX rate return
series, which does not exhibit a strong fat tails
behaviour, the EVT does not perform well at
conventional levels of significance, up to 98%, and
there are other methods that provide consistentlymore accurate estimates of the maximum loss (e.g. themoving average and the GARCH type models). It isonly at levels of significance higher than 99% that theEVT methods produce a prediction success ratesimilar to that of the other methods. However,these results are reversed when we look at the stockmarket index returns that exhibit clearly a fat tailsbehaviour. Here, the superiority of the EVT techni-ques at high levels of significance, in terms of theaccuracy of the estimates of maximum losses, isclearly evident.
Finally, in Fig. 11 we present the predicted one-dayahead correlation index of extreme returns that isbased on the estimation of the coefficient a from the
−0.3
−0.2
−0.1
0
0.1
0.2
0.3
0.4
0.5
12/4/2001 12/6/2001 12/8/2001 12/10/2001 12/12/2001 12/2/2002 12/4/2002
DatesRM094
Cor
rela
tion
coef
ficie
nt
EVT-POT GARCH(N)
Fig. 11. Forecasted correlation for CYP/USD vs. CGI returns (30 April 2001 to 19 April 2002)
−0.03
−0.02
−0.01
0
0.01
0.02
0.03
0.04
1 51 101 151 201 251
Returns GARCH(1,1) RM(0.94) EVT-BM(60)
Fig. 10. USD/CYP returns, negated and VaR (99%) estimates (30 April 2001 to 19 April 2002)
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Tiago de Oliveira (1973) formula. For comparisonreasons we have also estimated the correspondingcorrelation index by fitting a bivariate GARCHmodel where the variance and covariance equationsare modeled as GARCH(1,1) processes. As a sub-casewe also consider the restricted bivariate GARCH asimplied by the RM(0.94) specification. The obtainedvalues of the correlation index from the bivariateEVT are around 0.2 when the GARCH(1,1) methodgives estimates close to zero and the RM(0.94)extremely volatile estimates which however averageto zero as well.8 The evidence suggests that there hasbeen a very low correlation between exchange rateand the stock market daily returns in Cyprus. Thisconclusion holds even at crises periods since thecorrelation coefficient of extremes retains values closeto 0.20. Another interesting result is that the bearmarket conditions that characterize the backtestingperiod do not appear to have affected the extremecorrelation index.
The reasons for those findings can be traced to thecapital controls that restricted short-term borrowingby residents, the intervention policy of the centralbank of Cyprus as well as to the fact that thebubble in the Cyprus Stock exchange was mainlydomestically driven.
IV. Concluding Remarks
In this article we have applied the univariate andmultivariate EVT in order to derive different VaRestimates for two inherently unstable markets; theforeign exchange and the stock market. Theseestimates are compared to those obtained frommore ‘traditional’ methods of estimation through abacktesting exercise. The data for this exercise consistof the daily returns of the US dollar/Cyprus poundexchange rate and the CGI. The main conclusion wehave reached is that for a return series that is heavytailed distributed, i.e. the stock market returns in ourcase, the extreme value techniques give more accurateloss prediction results. However, this result is reversedif one attempts to apply this methodology on a seriesthat might not exhibit strong ‘fat’ tails characteristics,i.e. the foreign exchange returns in our case. We havealso derived estimates of the correlation index of theextreme observations of those two markets and weobtained substantial differences from the competingmodels. The main result here is that the correlation ofextreme returns between the Cyprus pound/USD
exchange rate and the Cyprus General Index dailyreturns is quite low but clearly higher than the onethat is based on the entire sample of observations.
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Appendix A. Conventional methods forthe Estimation of the VaR and theCorrelation Index
Let ðYtÞnt¼1 represent identically and
independently distributed, i.i.d., daily returns of a
financial asset price. We can then define VaRt(a), as
the conditional on the information set, Tt�1, �thquantile, i.e.
PrYt � VaRtðaÞ
It�1
� �¼ a ðA1Þ
Suppose now that ðYtÞnt¼1 follows the stochastic
process:
Yt ¼ �t þ et ¼ �t þ �t"t ðA2Þ
where �t ¼ EðYt=It�1Þ, �2t ¼ Eðe2t =It�1Þ and "t¼ (et/�t)
has the conditional distribution function �t(�).
Under the parametric approach we consider
specific distributions for �t(�) such as the Gaussian
N(0,1), the Student-t and the GED. Therefore,
VaRt(a) is estimated by inverting the distribution
function:
VaRtðaÞ ¼ �t þ��1t ðaÞ�t ðA3Þ
The conditional variance can be estimated by various
volatility models such as the moving average, MA,
variance or alternatively by one of the family of
GARCH models. In particular, the standard
GARCH(1,1) model is given by:
�2t ¼ �0 þ �1ðYt�1 � �tÞ
2þ �2
t�1 ðA4Þ
where �t ¼ ð1=TÞPT
i¼1 Yt�i. As a special case we will
be concerned with the EWMA specification, adopted
by the (RM) model of J. P. Morgan, under which:
�2t ¼ ��2
t�1 þ ð1� �ÞðYt�1 � �tÞ2
ðA5Þ
Riskmetrics has chosen �¼ 0.94 and �¼ 0.97 as the
optimal decay factor for daily and monthly data,
respectively.The second methodology we explored was based
on nonparametric approaches to model the distribu-
tion of returns. Historical simulation makes use of the
empirical quantiles of returns to estimate VaRs for a
given confidence level. The critical assumption behind
this approach is that the historical distribution of
returns will remain the same over the next periods.
Also, a feature of this method is that extrapolation
beyond past observations is impossible and therefore
extreme quantiles cannot be estimated. If a long
sample is chosen instead, then the method is unable to
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distinguish between high and low volatility periodsand as a result it might generate inaccurate estimates.
With the Monte Carlo, MC, simulation methodone simulates the future value of an asset based on anunderlying stochastic process. In this article theBrownian motion process, in its discrete time version,has been adopted for the asset price S, that is:
�St
St�1¼ Yt ¼ �t�t�tþ �t�1"t
ffiffiffiffiffiffi�t
p� ðA6Þ
where "t, is a zero mean, unit variance error term, and�t and �t are drift and volatility parameters. In theempirical investigation we have allowed for a possibletime-varying volatility structure where the volatilitycoefficient is being estimated by GARCH-normal,GARCH-t, GARCH-GED, RM(0.94) and MA(60).
In order to estimate the conditional correlationwith the ‘conventional’ approaches a bivariateGARCH model has been fitted to the data(Alexander, 1998). The specification of the model is
given by the conditional mean Equations A2 for eachone of the two variables Y1,t and Y2,t and thefollowing conditional variance and covariance equa-tions which are modeled as GARCH(1,1) processes invech parameterization:
h21, t ¼ �0 þ �1e21, t�1 þ �2h
21, t�1
h22, t ¼ 0 þ 1e22, t�1 þ 2h
22, t�1
h12, t ¼ 0 þ 1h12, t�1 þ 2ðY1, t�1 � �1, t�1Þ
� ðY2, t�1 � �2, t�1Þ
ðA7Þ
Under the Riskmetrics approach the followingparameter values apply: 0¼ 0, 1¼ 0.94, 2¼ 0.06.The conditional correlation is then given by:
�t ¼h12, t
h1, th2, tðA8Þ
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