LOYOLA COLLEGE (AUTONOMOUS), CHENNAI – 600 034
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M.Sc. DEGREE EXAMINATION – STATISTICS
SECOND SEMESTER – April 2009
S 815 – PROBABILITY THEORY
Date & Time: 04/05/2009 / 1:00 – 4:00 Dept. No. Max. : 100 Marks
SECTION-A (10 × 2=20)
Answer ALL the questions.
- With reference to tossing a regular coin once and noting the outcome, identify
completely all the elements of the probability space (Ω, A, P).
∞
- If P(An ) =1, n=1,2,3,… , evaluate P( ∩ An ) .
n=1
- Show that the limit of any convergent sequence of events is an event.
- Define a random variable and its probability distribution.
- Calculate E(X), if X has a distribution function F(x), where
F(x) = 0 if x<0
x/2 if o≤ x<1
- if x ≥ 1.
- If X1 and X2 are independent random variables and g1 and g2 are Borel functions, show
that g1(X1) and g2(X2 )are independent.
- State Glivenko-Cantelli theorem.
- Φ is the characteristic function (CF) of a random variable X, find the CF of (2X+3).
- State Kolmogorov’s strong law of large numbers(SLLN).
- State Lindeberg-Feller central limit theorem.
SECTION-B (5 × 8 = 40)
Answer any FIVE questions.
- Define the distribution function of a random variable X. State and establish its
defining properties.
- Explain the independence of two random variables X and Y. Is it true that if X and
Y are independent, X2 and Y2 are independent? What about the converse?
- State and prove Borel zero –one law.
- State and prove Kolmogorov zero-one law for a sequence of independent random
variables.
- Define convergence in probability. Show that convergence in probability implies
convergence in distribution.
- a) Define “Convergence in quadratic mean” for a sequence of random variables.
- b) X is a random variable, which takes on positive integer values. Define
Xn = n+1 if X=n
n if X=(n+1)
X otherwise
Show that Xn converges to X in quadratic mean. (2+6)
- Establish the following:
(a) If Xn → X with probability one, show that Xn → X in probability.
(b) Show that Xn → X almost surely if and only if for every є >0,
P [lim sup │ Xn – X│> є ]= 0
- Let { Xn ,n ≥1} be a sequence of independent random variables such that Xn has
uniform distribution on (-n, n). Examine whether the central limit theorem holds for
the sequence { Xn, n≥1}.
SECTION-C (2 x 20 = 40 marks)
Answer any TWO questions
19.a) Show that the probability distribution of a random variable is determined by its
distribution function.
- b) Show that the vector X =(X1, X2,…, Xp ) is a random vector if and only if Xj,
j =1, 2, 3… p is a real random variable.
- c) If X is a random variable with continuous distribution function F, obtain the
probability distribution of F(X). (6+8+6)
20.a) State and prove Kolmogorov’s inequality. (10 marks)
- b) State and prove Kolmogorov three series theorem for almost sure convergence of
the series Σ Xn of independent random variables. (10 marks)
21.a) If Xn and Yn are independent for each n, if Xn → X, Yn → Y, both in
distribution, prove that (Xn2 + Yn2) → (X2+Y2) in distribution. (10 marks)
- b) Let { Xn } be a sequence of independent random variables with common frequency
function f(x) = 1/x2 , x=1,2,3,… Show that Xn /n does not converge to zero with
probability one. (10 marks)
22.a) State and prove Levy continuity theorem for a sequence of characteristic
functions.(12 marks).
b)Let {Xn} be a sequence of normal variables with E (Xn) = 2 + (1/n) and
var(Xn) = 2 + (1/n2), n=1, 2, 3…Examine whether the sequence converges in
distribution.(8 marks).
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