Three hours. To be supplied by the Examinations Office: Mathematical Formula Tables and Statistical Tables THE UNIVERSITY OF MANCHESTER.

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Three hours To be supplied by the Examinations Office: Mathematical Formula Tables and Statistical Tables THE UNIVERSITY OF MANCHESTER EXTREME VALUES AND FINANCIAL RISK Examiner: Answer QUESTION 1, QUESTION 2 and any FOUR of the remaining questions. University-approved calculators may be used 0 END OF EXAMINATION PAPER 1 of 10

1. Consider a bivariate distribution specified by the joint survival function ] F (x, y) = Pr(X > x, Y > y) = exp [ θy2 x + y + θy x y for x > 0 and y > 0. (a) Show that the distribution is a bivariate extreme value distribution. (b) Derive the joint cdf. (c) Derive the conditional cdf of Y given X = x. (d) Derive the conditional cdf of X given Y = y. (e) Derive the joint pdf. (6 marks) 2 of 10 Turn to next page

2. Suppose that stock returns of a company can be modeled by an exponential distribution with random rate parameter λ. (a) Determine the actual distribution of stock returns if λ has an exponential distribution with rate parameter a, where a is an unknown parameter. (b) Find the mean of the distribution in part (a). (c) Find the variance of the distribution in part (a). (b) If x 1, x 2,..., x n is a random sample from the actual distribution in part (a), derive the equation for the maximum likelihood estimate of the parameter a. 3 of 10 Turn to next page

3. Suppose X 1, X 2,..., X n is a random sample with cdf F ( ). State the Extremal Types Theorem for M n = max(x 1, X 2,..., X n ). You must clearly specify the cdfs of each of the three extreme value distributions. (6 marks) State in full the necessary and sufficient conditions for F ( ) to belong to the domain of attraction of each of the three extreme value distributions. (6 marks) Consider a class of distributions defined by the cdf and the pdf F (x) = 1 Γ(a) x { log[1 G(y)]} a 1 g(y)dy f(x) = 1 Γ(a) { log[1 G(x)]}a 1 g(x) where a > 0, G( ) is a valid cdf, and g(x) = dg(x)/dx. Show that F belongs to the same max domain of attraction as G. (8 marks) 4 of 10 Turn to next page

4. Suppose a portfolio is made up of three assets with X, Y and Z denoting the corresponding prices. Suppose also that the joint distribution of X, Y and Z is specified by the survival function F (x, y, z) = [ 1 + x a + y b + z ] d c for x > 0, y > 0, z > 0, a > 0, b > 0, c > 0, and d > 0. Find the following: (a) The cdf of M = max(x, Y, Z). (b) The pdf of M. (c) The nth moment of M. (d) The cdf of L = min(x, Y, Z). (e) The pdf of L. (f) The nth moment of L. 5 of 10 Turn to next page

5. State the domain of attraction (if there is one) for each of the following distributions: (i) The exponentiated exponential distribution given by the cdf F (x) = [1 exp( x)] α, for x > 0 and α > 0. (ii) The exponentiated exponential geometric distribution given by the cdf F (x) = {1 exp( βx)} α 1 p + p {1 exp( βx)} α, for x > 0, α > 0, β > 0 and 0 < p < 1. (iii) The exponential-negative binomial distribution given by the cdf F (x) = 1 (1 p)k exp( kβx) [1 p exp( βx)] k, for x > 0, k > 0, 0 < p < 1 and β > 0. (iv) The degenerate distribution given by the pmf { 1, if x = x0, p(x) = 0, if x x 0. (v) The Poisson distribution given by the pmf p(x) = λx exp( λ), x! for λ > 0 and x = 0, 1,.... 6 of 10 Turn to next page

6. If X is an absolutely continuous random variable with cdf F ( ), then define VaR p (X) and ES p (X) explicitly. (3 marks) If X is a uniform [a, b] random variable derive explicit expressions for VaR p (X) and ES p (X). (3 marks) Suppose X 1, X 2,..., X n is a random sample from uniform [a, b], where both a and b are unknown. (i) Write down the joint likelihood function of a and b. (1 marks) (ii) Show that the maximum likelihood estimator (mle) of a is â = min(x 1, X 2,..., X n ). (1 marks) (iii) Show that the mle of b is b = max(x 1, X 2,..., X n ). (iv) Deduce the mles of VaR p (X) and ES p (X). (v) Show that the mle of VaR p (X) is biased. (vi) Show that the mle of ES p (X) is also biased. (1 marks) 7 of 10 Turn to next page

7. Suppose a portfolio is made up of α assets where α is unknown. Suppose also that the price of each asset, say X i, i = 1, 2,..., α, is an exponential random variable with an unknown parameter λ. Then Y = max (X 1,..., X α ) will be the price of the most expensive asset. (i) Find the cdf of Y. (ii) Find the pdf of Y. (iii) Find the nth moment of Y. (iv) Find the value at risk of Y. (v) Find the expected shortfall of Y. (vi) If y 1, y 2,..., y n is a random sample on Y derive the equations for the maximum likelihood estimates of α and λ. 8 of 10 Turn to next page

8. Let X i denote the stock price of a product at day i. Suppose X i are independent exponential random variables with parameters λ i. Find explicit expressions for the following: (a) Pr (X 1 < X 2 ). (b) Pr (X 1 < X 2 < X 3 ). (c) Pr (X 1 < X 2 < X 3 < X 4 ). You must show full working for each probability. Now deduce the expression for the general probability Pr (X 1 < X 2 < < X k ). Calculate the values of Pr(X 1 < X 2 ), Pr(X 1 < X 2 < X 3 ), Pr(X 1 < X 2 < X 3 < X 4 ), and Pr(X 1 < X 2 < < X k ) for the particular case λ i = λ for all i. 9 of 10 Turn to next page

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