library(nvmix) library(RColorBrewer) doPDF <- FALSE
A random vector $\mathbf{X}=(X_1,\dots,X_d)$ follows a normal variance mixture, in notation $\mathbf{X}\sim \operatorname{NVM}_d(\mathbf{\mu},\Sigma,F_W)$, if, in distribution, $$ \mathbf{X} = \mathbf{\mu}+\sqrt{W}A\mathbf{Z}, $$ where $\mathbf{\mu}\in\mathbb{R}^d$ denotes the location (vector), $\Sigma=AA^\top$ for $A\in\mathbb{R}^{d\times k}$ denotes the scale (matrix) (a covariance matrix), and the mixture variable $W\sim F_W$ is a non-negative random variable independent of $\mathbf{Z}\sim\operatorname{N}_k(\mathbf{0},I_k)$ (where $I_k\in\mathbb{R}^{k\times k}$ denotes the identity matrix). Both the Student's $t$ distribution with degrees of freedom parameter $\nu>0$ and the normal distribution are normal variance mixtures; in the former case, $W\sim\operatorname{IG}(\nu/2, \nu/2)$ (inverse gamma) and in the latter case $W$ is almost surely constant (taken as $1$ so that $\Sigma$ is the covariance matrix of $\mathbf{X}$ in this case).
It follows readily from the stochastic representation that linear combinations of multivariate normal variance mixtures are univariate normal variance mixtures. Let $\mathbf{a}\in\mathbb{R}^d$. If $\mathbf{X}\sim \operatorname{NVM}_d(\mathbf{\mu}, \Sigma,F_W)$, then $\mathbf{a}^\top \mathbf{X} \sim \operatorname{NVM}_1(\mathbf{a}^\top\mathbf{\mu}, \mathbf{a}^\top\Sigma\mathbf{a},F_W)$.
If $\mathbf{X}$ models, for instance, financial losses, $\mathbf{a}^\top \mathbf{X}$ is the loss of a portfolio with portfolio weights $\mathbf{a}$. It is then a common task in risk management to estimate risk measures of the loss $\mathbf{a}^\top \mathbf{X}$. We consider the two prominent risk measures value-at-risk and expected shortfall.
In the following, assume without loss of generality that $X\sim \operatorname{NVM}_1(0, 1, F_W)$, the general case follows from a location-scale argument.
The value-at-risk of $X$ at confidence level $\alpha\in(0,1)$ is merely
the $\alpha$-quantile of $X$. That is,
$$ \operatorname{VaR}_\alpha(X) = \inf{x\in[0,\infty):F_X(x)\ge \alpha},$$
where $F_X(x)=\mathbb{P}(X\le x)$ for $x\in\mathbb{R}$ is the distribution function of
$X$. Such quantile can be estimated via the function qnvmix()
, or equivalently,
via the function VaR_nvmix()
of the R
package nvmix
.
As an example, consider $W\sim\operatorname{IG}(\nu/2, \nu/2)$ so that $X$ follows a $t$
distribution with $\nu$ degrees of freedom. In this case, the quantile is known.
If the argument qmix
is provided as a string, VaR_nvmix()
calls qt()
;
if qmix
is provided as a function or list, the quantile is internally estimated
via a Newton algorithm where the univariate distribution function $F_X()$ is
estimated via randomized quasi-Monte Carlo methods.
set.seed(1) # for reproducibility qmix <- function(u, df) 1/qgamma(1-u, shape = df/2, rate = df/2) df <- 3.5 n <- 20 level <- seq(from = 0.9, to = 0.995, length.out = n) VaR_true <- VaR_nvmix(level, qmix = "inverse.gamma", df = df) VaR_est <- VaR_nvmix(level, qmix = qmix, df = df) stopifnot(all.equal(VaR_true, qt(level, df = df))) ## Prepare plot pal <- colorRampPalette(c("#000000", brewer.pal(8, name = "Dark2")[c(7, 3, 5)])) cols <- pal(2) # colors if(doPDF) pdf(file = (file <- "fig_VaR_nvmix_comparison.pdf"), width = 7, height = 7) plot(NA, xlim = range(level), ylim = range(VaR_true, VaR_est), xlab = expression(alpha), ylab = expression(VaR[alpha])) lines(level, VaR_true, col = cols[1], lty = 2, type = 'b') lines(level, VaR_est, col = cols[2], lty = 3, lwd = 2) legend('topleft', c("True VaR", "Estimated VaR"), col = cols, lty = c(2,3), pch = c(1, NA)) if(doPDF) dev.off()
Another risk measure of great theoretical and practical importance is the expected-shortfall. The expected shortfall of $X$ at confidence level $\alpha\in(0,1)$ is, provided the integral converges, given by $$ \operatorname{ES}\alpha(X) = \frac{1}{1-\alpha} \int\alpha^1 \operatorname{VaR}u(X)du.$$ If $F_X()$ is continuous, one can show that $$ \operatorname{ES}\alpha(X) = \operatorname{E}(X \mid X > \operatorname{VaR}_\alpha(X)).$$
The function ES_nvmix()
in the R
package nvmix
can be used to estimate
the expected shortfall for univariate normal variance mixtures. Since these
distributions are continuous, we get the following:
$$ (1-\alpha) \operatorname{ES}\alpha(X) = \operatorname{E}\left(X \mathbf{1}{{X>\operatorname{VaR}\alpha(X)}}\right)= \operatorname{E}\left( \sqrt{W} Z \mathbf{1}{{\sqrt{W} Z > \operatorname{VaR}_\alpha}}\right) $$
$$= \operatorname{E}\Big( \sqrt{W} \operatorname{E}\big(Z \mathbf{1}{{Z> \operatorname{VaR}\alpha(X)/\sqrt{W}}} \mid W\big)\Big)= \operatorname{E}\left(\sqrt{W} \phi(\operatorname{VaR}_\alpha(X) / \sqrt{W})\right) $$
Here, $\phi(x)$ denotes the density of a standard normal distribution and we used
that $\int_k^\infty x\phi(x)dx = \phi(k)$ for any $k\in\mathbb{R}$. Internally, the
function ES_nvmix()
estimates $\operatorname{ES}_\alpha(X)$ via a randomized quasi-Monte
Carlo method by exploiting the displayed identity.
In case of the normal and $t$ distribution, a closed formula for the
expected shortfall is known; this formula is then used by ES_nvmix()
if
qmix
is provided as string.
ES_true <- ES_nvmix(level, qmix = "inverse.gamma", df = df) ES_est <- ES_nvmix(level, qmix = qmix, df = df) ## Prepare plot if(doPDF) pdf(file = (file <- "fig_ES_nvmix_comparison.pdf"), width = 7, height = 7) plot(NA, xlim = range(level), ylim = range(ES_true, ES_est), xlab = expression(alpha), ylab = expression(ES[alpha])) lines(level, ES_true, col = cols[1], lty = 2, type = 'b') lines(level, ES_est, col = cols[2], lty = 3, lwd = 2) legend('topleft', c("True ES", "Estimated ES"), col = cols, lty = c(2,3), pch = c(1, NA)) if(doPDF) dev.off()
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