Estimating VaR of
portfolio by conditional copula-GARCH method
Contents
1. Introduction
2. Theory of copula
2.1 Introduction to copula
2.2 Copula family
2.3 Estimation method
2.4 Estimation of VaR
3. Empirical results
3.1 The data and the marginal
distribution
3.2 Copula modeling
3.3 Estimation of VaR
4. Conclusion
1.
Introduction
The
traditional approaches for estimating VaR are based on the assumption of
multivariate normal distribution and the linear correlation. However, in
reality, the distribution of financial data usually has fatter tails than
normal distributions. Hence, it is shown in many empirical works that such
multivariate distributions do not provide adequate results due to the presence
of asymmetry.
In
order to overcome these problems, we combine copula and the forecast function
of the GARCH model, and then propose the conditional copula-GARCH method to
compute the VaR of portfolios. Copula in particular has recently become one of
the most significant new tools, it is generally applied in the financial field,
such as risk management, portfolio allocation, derivative asset pricing etc. In
our work we focus on portfolio risk management, especially in estimating VaR.
Copula theory allows us to construct a flexible multivariate distribution with
different margins and different dependent structures.
In
the empirical analysis, we construct a portfolio composed of NASDAQ and STI
indices, and apply various copulas completely with different marginal
distribution to estimate VaR for the portfolio. In addition, compared with
traditional methods, including the historical simulation method,
variance–covariance method and EWMA model, we prove that the Student-t
copula-GARCH model captures the VaR of the portfolio more successfully.
The
rest of the paper is organized as follows. Section 2 presents GARCH models for
marginal distributions. Section 3 presents Sklar’s theorem and the copula
families. In addition, we introduce the estimation procedures of VaR. Section 4
presents the empirical analysis and results, followed by a conclusion in
Section 5.
2. Theory of copula
In our project, we use
the joint distribution function of returns of individual assets in a portfolio
to compute the portfolio’s VaR. We first find marginal distribution of
individual returns by GARCH model and then derive the joint distribution of the
portfolio by using copula.
2.1 Introduction to copula
This part illustrates
the statistical background of how we get the joint distribution of a random
vector when its marginal distributions are all known, which is called copula
method.
Let
denote a random vector with marginal
cumulative distribution function
respectively. Applying the probability
integral transform:
Then copula is defined as the joint cumulative
distribution function of:
Sklar’s theorem. Every multivariate cumulative distribution function F of a random vector
Where c is the copula density function.
So how can we find an
appropriate copula? Does it satisfy any conditions? A lemma below tells us an
important property of copula.
Lemma. Assume ξ has continuous cumulative distribution
function F(x), then θ = F(ξ) follows uniform distribution on [0,1].
Property. The copula’s marginal probability
distribution of each variable is uniform.
This property tells us which type of cdf can be
selected into the copula family.
In
practice, we need to find the best copula fit for our data. We choose copula
from a copula family and compute the model AIC and BIC to determine the best
one.
Copula family:
Gaussian copula, the Student-t copula, Clayton copula,
Rotated-Clayton copula, Frank copula, Plackett copula, Gumbel copula, the
Rotated-Gumbel copula and so on.
For our
project, Gaussian copula and Student-t copula perform very well.
Gaussian copula:
where Φ is the cumulative distribution function of a
standard normal and Φρ is the joint cumulative distribution function of a
multivariate normal distribution with mean vector zero and covariance matrix ρ.
Student-t copula:
Student-t copula:
where ρ is the correlation matrix of multivariate
Student-t distribution and v is the degree of freedom.
Denote θ the set of all
parameters of both the marginal distribution and copula. We use maximum
likelihood method (MLE) to estimate this θ. According to the previous result:
the log-likelihood function is:
2.4 Estimation of VaR
Suppose our portfolio has two assets X_1,t and X_2,t. The weight of X_1,t is 0.5 and the confidence level is 0.05. We
can calculate the VaR by definition:
Where c
is the copula function and f is the marginal distribution.
We also
calculate four other different methods of VaR: Historical simulation; Variance-covariance
method; Exponentially weighted moving average(EWMA); and the traditional
GARCH-VaR model.
3.
Empirical results
3.1 The data and the
marginal distribution
In order to see the performance of
copula-GARCH method, we conduct model estimation and analysis based on
real-world data. We simply choose two major stock indices, STI and SPX
(Singapore Straits Time Index, and S&P500 Index), from Oct 19, 2010 to Oct
17, 2019 with 2199 daily observations. Price data comes from Bloomberg
database, and we transfer them into return data by:
Where Pt is the value of index at
time t. In addition, to eliminate the spurious correlation caused by holiday
divergence, we eliminate those observations which coincide with holidays of
either Singapore or the U.S. The market returns and absolute returns of STI and
SPX are shown in Fig.1.
Fig.1. Daily returns and absolute
returns of STI and SPX
In Fig.1, you can find volatility
significant clustering in both historical data. Hence, we use ARCH test to
examine the serial correlation of squared return, i.e. ARCH effects (see Table
1)
Table 1 exhibits descriptive
statistics on returns and the result of ARCH tests. We can find that both STI
and SPX has a negative skewness. The LM(lag=k) results indicate that ARCH
effects can be found in both SPI and SPX returns.
Hence, we consider the GARCH model
as the univariate marginal model, to fit for the return series as the initial
models with normal and student-t distribution. Table 2 exhibits the MLE
results, Ljung-box test and ARCH test for model adequacy, as well as the AIC
and BIC criterion for model selection.Table 2. Parameter estimates of
GARCH model and statistical t
From Table 2, we find that model parameters are significant at 5% significant level, and the result of Ljung-box tests and ARCH tests shows no anymore residual autocorrelations and ARCH effects. Therefore, we conclude that both GARCH-n and GARCH-t models are adequate.
3.2 Copula
modeling
We use the copula method based on
the marginal distribution discussed above. We use MLE method, and the copula
functions will be fitted to the residuals series. The result of copula-GARCH
modeling is shown in Table 3.
Table 3. Parameter estimates for
Gaussian and Student-t copula and model selection statistics
In Table 3, we can obviously find
that the best fitting copula function is student-t copula, whose AIC and BIC
are generally smaller compared to Gaussian copula. This means that, student-t
copula performs better in describing the dependence structure of the bivariate
return series. In particular, the best fitting model among the four model we
discuss is the student-t copula GARCH-n model.
3.3 Estimation of VaR
3.3 Estimation of VaR
We initially uses the sample-in data, which contains 1699
return observations, to estimate VaR1700, and at each new observation we
re-estimate VaR, until the sample-out observations we have updated are used up
and we will get 500 tests for VaR.
The numbers of
violations in Table 5 are the numbers of sample observations being located out
of the critical value. The mean error shows for each copula function, the total
absolute discrepancy per marginal model between the observed and expected
number of violations at α = 0.05 and 0.01.
From the results in Table 5, the Student-t copula GARCH-n method shows the
minimum mean error with a 95% and 99% level of confidence. That is, the
Student-t copula GARCH-n is the most accurate model for estimating VaRs of the
portfolio. Besides, Fig. 2 shows the VaR plot we estimate using the Student-t
copula with a marginal distribution, the GARCH-n model at α
= 0.05 and 0.01. In this Figure the VaR of portfolio is located
almost below the portfolio returns, and describes the expectation of investment
loss well.
Figure
3. Comparison of VaR using various methods at α = 0.05
It is also obvious to
see the VaR of the historical simulation method and variance-covariance method
are underestimated and this represents the highest mean error at α
= 0.05 and 0.01. The univariate GARCH-VaR method is better
than the HS and VC methods, but it still underestimates VaR, and the mean error
is still high. The EWMA method is also not as good as the method of conditional
copula-GARCH. The various VaRs we estimate are shown in Fig. 3 with α
= 0.05. In this figure we can see that trends of the HS and VC
methods are more flat and these methods can not reflect the risk of portfolio
returns with time-varying. The methods of GARCH reflect too much while the
estimation of EWMA is always not enough. The t-copula-GARCH-n method captures
the extremes most successfully compared with others.
4. conclusion
Table 5. Number of violations of VaR estimation.
the correlation among the price or volatility behaviors of the financial assets within a portfolio is crucial for the proper estimation of the VaR amount. However, restrictions on the joint distributions of the financial assets within the portfolio might decrease the performance of the VaR estimation. We describe a model for estimating portfolio VaR by the conditional copula-GARCH model, which allows for a very flexible joint distribution by splitting the marginal behaviors from the dependence relation, and which is lack of in traditional methods. We estimates different copulas with different univariate marginal distributions, and traditional methods to compare the results. The Student-t copula describes the dependence structure of the portfolio return series quite well, in which we choose it by the AIC and BIC of the model criterion, producing the best results of the reliable VaR limit. The copula method has the feature of flexibility in distribution, which is more appropriate in studying highly volatile financial markets compared with traditional methods.
4. conclusion
Table 5. Number of violations of VaR estimation.
the correlation among the price or volatility behaviors of the financial assets within a portfolio is crucial for the proper estimation of the VaR amount. However, restrictions on the joint distributions of the financial assets within the portfolio might decrease the performance of the VaR estimation. We describe a model for estimating portfolio VaR by the conditional copula-GARCH model, which allows for a very flexible joint distribution by splitting the marginal behaviors from the dependence relation, and which is lack of in traditional methods. We estimates different copulas with different univariate marginal distributions, and traditional methods to compare the results. The Student-t copula describes the dependence structure of the portfolio return series quite well, in which we choose it by the AIC and BIC of the model criterion, producing the best results of the reliable VaR limit. The copula method has the feature of flexibility in distribution, which is more appropriate in studying highly volatile financial markets compared with traditional methods.
References
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3. Lu, X. F.,
Lai, K. K. & Liang, L. (2014). Portfolio value-at-risk estimation in energy
futures markets with time-varying copula-GARCH model. Annals of Operations
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