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Homework answers / question archive / 1) Let (W, F, P) be a probability space on which the following random variables are defined
1) Let (W, F, P) be a probability space on which the following random variables are defined. Consider the binomial model with 0 < d < 1 + r < u. Let the risk-neutral probabilities be given by
P = 1 + r – d/u – d, q = u – 1 – r/u – d.
Toss a coin repeatedly and assume the probability of head on each toss is p and probability of tail on each toss is q. Let
Xj = 1 if the jth toss results in a head
-1 if the jth toss results in a tail.
Where the Xj’s are i.i.d(independent and identically distributed). Consider the stochastic process M0, M1, M2,... defined by M0 = 0
Mn = Sj=1n Xj, n ³ 1.
Suppose the price Sn of a risky asset at time n is given by
Sn = S0eMn log u
Where d = 1/u. The discounted stock value is defined by
Yn = Sn/(1 + r)n
a. Find E|Sn] and Var[Sn].
b. Show that the discounted stock value Yn is a martingale with respect to Fn = s(S1, S2, ..., Sn).
2) Let (W, F, P) be a probability space and let {W(t), t > 0} be Brownian motion with respect to the filtration Ft, t > 0.
a. Let X(t) = W3(t) — 3tW(t). Is X(t) a martingale?
b. For l Î R, show that the following hyperbolic processes:
X(t) = e-1/2l2t cosh(lW(t))
is a martingale. (Hint: cosh(z) = ez + e-z/2)
3) Let (W, F,P) be a probability space and let {W(t),t > 0} be Brownian motion with respect to the filtration Ft , t > 0. By considering the geometric Brownian motion
S(t) = S(0)e(r-1/2s2)t+sW(t) a Î R
where r is the mean rate of return, s > 0, S(0) > 0.
Show that the stock price S(t) is a Markov process. That is for any Borel-measurable function f(y), and for any 0 < s < ¢ the function
g(x) = ò¥0 f(y)p(t, x, y)dy
where t = t - s, v= (r — 1/2s2) and
p(t, x, y) = 1/(syÖ2pt) e – (log(y/x) – vt)2/2s2(t – s) y > 0,
satisfies
E[f(S(t))|F(s)] = g(S(s)).
p(t, x, y) is the transition density for S(t).
4) (Black-Schole-Merton formula) Let (W, F, P) be a probability space. Suppose the price S(t) of a risky asset at time t follows the geometric Brownian motion
S(t) = S(0)e(r-1/2s2)t+sW(t) t ³ 0
where r is the mean rate of return, S(0) > 0 is the initial asset price and W(t) is a Brownian motion. Let K > 0.
a. Find E[S(t)] and Var[S(t)].
b. Show that, for T > 0,
E [e-rT (S(T) — K)+] = S(0)F (d+(T, S(0))) — Ke-rTF (d_(T, S(0)))
where
d+(T, S(0)) = 1/sÖT [In (S(0)/K) + (r + ½ s2) T]
d-(T, S(0)) = 1/sÖT [In (S(0)/K) + (r – ½ s2) /T]
and F is the cumulative standard normal distribution function
F(y) = 1/Ö2p òy-¥ e-1/2 z2 dz = 1/Ö2p ò¥-y e-1/2z2dz.
1. Suppose X and Y are uniform random variables on |0, 1| and are independent.
a. Determine the value of Cov(X, Y + 2).
b. Determine the value of E[X2Y2]
c. Determine the value of E[euX+vY] where u and v are real numbers.
2. Let X be a standard normal random variable and let Y = X2.
a. Show that X and Y are not independent.
b. Show that E[XY] = E|X] . E[Y].
3. Let X = (X1, X2) be an ordered pair that takes the points (—1, 1), (0, 0), and (1, 1) with probabilities 1/4, 1/2, and 1/4.
PX(x1, x2) = ¼ if x1= -1 and x2 = 1
= ½ if x1 = 0 and x2 = 0
= ¼ if x1 = 1 and x2 = 1
= 0 otherwise
a. Show that X1 and X2 are not independent.
b. Show that E[X1X2] = E[X1] . E[X2].
4. Let W = {1,2,3,4,5,6}, F = 2W. Let P denotes a probability measure on (W, F) with P({1}) = P({2}) = 1/12 and P({3}) = P({4}) = 1/4. Find P({5}) and P({6}) if the events {1,3,4} and {1,2,3,5} are independent.
5. Suppose a random variable (X, Y, Z) is equally likely to take any one of the values (1,0,0), (0,1,0), (0,0,1), (1,0,1), (1, 1,1).
a. Find E(X|Y).
b. Find E(Y|X).
6. Let W = {a,b,c,d}, F = 2W and P({w}) = ¼ for w Î W. Define
X(w) = 0 if w = a, d
= -1 if w = b
= 1 if w =c
Y(w) = -1 if w = a, b
= 1 if w = c, d
a. List the sets in s(X) and s(Y).
b. Find E[X|Y].
c. Find E[Y|X].
7. a. For s < t, compute E[eW(t)-W(s)].
b. Show that Cov(W(s), W(t)) = min{s, t}
c. Show that Corr(W(s), W(t)) = Ömin{s,t}/max{s,t}.
8. Let W(t) be a Brownian motion and let F(t) be a filtration for the Brownian motion.
a. Show that W(t) is a martingale.
b. Is W2(t) a martingale?
c. Show that the process Z(t), t > 0 defined by
Z(t) = e-1/2s2t+sW(t)
a martingale for 0 < s < t.
9. Let Yn be a martingale such that Y0 = 0. Show that
a. E[Yn] = 0.
b. Cov(Yn+1, Yn)
10. Suppose X is random variable (measurable with respect to F) such that X is integrable. Let
Yn = E[X|Fn]
Show that Yn is a martingale with respect to Fn. (Hint Show that E[Yn+1|Fn = Yn).
11. If X(t) = eW(t), compute the following
a. Show that X(t) is not a martingale.
b. Show that e-t/2X(t) is a martingale.
c. Show Y(t) = eaW(t)-1/2a2t is a martingale for any real number a.
12. Let (W, F, P) be a probability space and let {W(t),t > 0} be Brownian motion with respect to the filtration Ft, t > 0. For l Î R show that
Y(t) = e-1/2l2t sinh(lW(t))
are martingales.
13. a. Compute E[W3(t)] and E[/W4(t)|
b. Find E[(W2(t)—t)(W2(s) —s)]. (Hint: use the fact that of W2(t) - t is a martingale).
c. Compute E[W2(t)W2(s)].
d. Compute Cov(W2(t), W2(s)).
e. Find Corr(W2t, W2s)
14. If X(t) = eW(t), compute the following
a. Cov(X(s), X(t)).
b. Corr(X(s), X (t))
c. Show that
E[eW(s)+W(t)] = et+s/2 emin{s, t}.
15. The process Y(t) = W(t) — tW(1) is called the Brownian bridge fixed at both 0 and 1.
a. What is the distribution of Y(t)?
b. Find E[Y2(t)).
c. Find Var[Y2(t)].
16. Define a new process by Y(t) = tW(1/t), t > 0, and define Y0 = 0.
a. Find the distribution of Y(t)
b. Find the probability density of Y(t)
c. Compute Cov(Y(s), Y(t))
d. Compute E[Y (t) — Y(s)] and Var[Y (t) — Y(s)].
17. Consider the binomial model with 0 < d < 1 + r < u. Let the risk-neutral probabilities be given by
P = 1 + r – d/u – d, q = u – 1 – r/u – d.
Toss a coin repeatedly. Assume the probability of head on each toss is p and probability of tail on each toss is q. Let
Xj = 1 if the jth toss results in a head
= -1 if the jth toss results in a tail.
where the Xi’s are i.i.d. Consider the stochastic process M0, M1, M2,... defined by M0 = 0
Mn = Sj=1n Xj, n ³ 1.
Suppose the price S,, of a risky asset at time n is given by
Sn = S0eMn log u.
Where d = 1/u. Show that the discounted stock value
Yn = Sn/(1+r)n
is a martingale with respect to Fn = s(S1, S2, ..., Sn). (Hint: show that E[Yn+1|Fn] = Yn).
18. Let (W, F, P) be a probability space. Let {Fn}n³1 be a filtration. Let Mn denote the symmetric random walk with Zn = Mn — Mn-1
i. Calculate g(l) = E[elZn].
il. Let
Yn = exp{lMn — n log g(l)}.
Show that E[Yn+1|Fn] = Yn.
(Trick for discrete exponential martingale: is to consider E [Yn+1/Yn Yn|Fn])
iii. Is Yn = M2n —n a martingale?
iv. Is Yn = M3n — 3nMn a martingale?
v. Suppose q Î R and let
Yn = (sechq)n eqMn n = 0,1,2,....
Is Yn a martingale?. (Recall that sech(z) = 2/ez+e-z)
19. Let (W, F, P) be a probability space and let {W(t),t > 0} be Brownian motion with respect to the filtration Ft, t ³ 0.
a. Show that X(t) = W2(t) — t is a martingale.
b. For l Î R, show that the following hyperbolic processes:
X(t) = e-1/2l2t cosh(lW(t))
is a martingale. (Hint: Use the identity cosh(z) = ex+e-z/2)
c. Show that X(t) = W3(t) — 3tW(t) is a martingale.
d. Find Corr(W2(t), W2(s)).
20. Let W(t) : t > 0 be a Brownian motion and let F(t),t > 0 be a filtration for this Brownian motion. Show that W(t) : t > 0 is a Markov process.
That is
E[f(W(t))|F(s)] = g(W(s))
for 0 < s < t, where f and g are Borel measurable functions.
21. Let (W, F, P) be a probability space and let {W(t),t > 0} be Brownian motion with respect to the filtration F(t), t > 0. By considering the process
X(t) = mt + cW(t)
where w Î R, c > 0.
Show that for any Borel-measurable function f(y), and for any 0 < s < t the function
g(x) = 1/cÖ2p(t-s) ò¥-¥ f(y)e[-1/2[(y-m)(t-s)-x)2/c2(t-s)]dy.
Satisfies E[f(X(t))|F(s)] = g(X(s)), and hence X(t) has a Markov property. We may write g(x) as
g(x) = ò¥-¥ f(y)p(t, x, y)dy, where t = t — s and
p(t, x, y) = 1/cÖ2pt e-1/2[(y-mt-x)2/e2(t-s)]dy.
is the transition density for X(t).
22. Let (W, F, P) be a probability space and let {W(t),t > 0} be Brownian motion with respect to the filtration F(t), t > 0. By considering the geometric Brownian motion
S(t) = S(0)e(r-1/2s2)t+sW(t) a Î R
where a Î R, s > 0, S(0) > 0.
Show that the stock price S(t) is a Markov process. That is for any Borel-measurable function f(y), and for any 0 < s < t the function
g(x) = ò¥0 f(y)p(t, x, y)dy
Where t = t – s, v = (r – 1/2s2) and
P(t, x, y) = 1/syÖ2pt e-1/2 (log(y/x)-vt)2/2s2(t-s) y > 0,
satisfies
E[f(S(t))|F(s)| = g(S(s)).
p(t, x, y) is the transition density for S(t).
23. (Black-Schole-Merton formula) Let (W, F, P) be a probability space. Suppose the price S(t) of a risky asset at time t follows the geometric Brownian motion
S(t) = S(0)e(r-1/2s2)t+sW(t) t ³ 0
where r > 0 is the mean rate of return, S(0) > 0 is the initial asset price and W(t) is a Brownian motion. Let K > 0.
a. Find the probability density of S(t).
b. Find E[S(t)] and Var[S(t)].
c. Show that, for T > 0,
E [e-rT (S(T) — K)+] = $(0)f (d+(T, $(0))) — Ke-rTf (d_(T, S(0)))
Where
d+(T, S(0)) = 1/sÖT[In (S(0)/K) + (r+1/2s2)T]
d-(T,S(0)) = 1/sÖT [In(S(0)/K) + (r-1/2s2)T]
and f is the cumulative standard normal distribution function
f(y) = 1/Ö2p òy-¥e-1/2z2dz = 1/Ö2pò¥-ye-1/2z2dz.
24. Let (W, F, P) be a probability space and let {W(t),t > 0} be a Brownian motion process. Show that the quadratic variation of W up to time T > 0 is
Limn®¥ Sn-1i=0(W(ti+1) – W(ti))2m.s.= T.
Where ti = iT/n, 0 = t0 < t1 < t2 < … < tn-1 < tn = T, n Î N.
25. Let (W, F, P) be a probability space and let {W(t), t > 0} be a Brownian motion process. Show that the following cross-variation between W (t) and t, and the quadratic variation of t, are
Limn®¥ Sn-1i=0 (W(ti+1) – W(ti))(ti+1-ti) =m.s. 0
Limn®¥ Sn-1i=0(ti+1 – ti)2 = 0
Where ti = iT/n, 0 = t0 < t1 < t2< … <tn-1 < tn = T, n Î N.
26. Let a and s > 0 be constants, and define the geometric Brownian motion
S(t) = S(O)e(a-1/2s2)t+sW(t).
Show that
s2 » 1/T2-T1 Sn-1i=0(In(S(ti+1)/S(ti)))2
Where
T1 = t0 < t1 < t2 <---<tn-1 < tn =T2
and ti = T1 + i(T2 – T1)/n.
