Loyola College M.Sc. Statistics Nov 2004 Mathematical Statistics – I Question Paper PDF Download

LOYOLA COLLEGE (AUTONOMOUS), CHENNAI –600 034

M.Sc., DEGREE EXAMINATION – MATHEMATICS

THIRD SEMESTER – NOVEMBER 2004

ST 3951 – MATHEMATICAL STATISTICS – I

02.11.2004                                                                                                           Max:100 marks

1.00 – 4.00 p.m.

 

SECTION – A

 

Answer ALL the questions                                                                            (10 ´ 2 = 20 marks)

  1. Find C such that f (x) = C satisfies the conditions of being a pdf.
  2. Let a distribution function be given by

0                 x < 0

F(x) =        0 £ x < 1

1            x ≥  1

 

Find     i) Pr               ii) P [X = 0].

  1. Find the MGF of a random variable whose pdf is f (x) = , -1 < x < 2, zero elsewhere.
  2. If the MGF of a random variable is find  Pr [X = 2].
  3. Define convergence in probability.
  4. Find the mode of a distribution of a random variable with pdf

f (x) = 12x2 (1 – x), 0 < x < 1.

  1. Define a measure of skewness and kurtosis using the moments.
  2. If A and B are independent events, show that AC and BC are independent.
  3. Show that E (X) = for a random variable with values 0, 1, 2, 3…
  4. Define partial correlation.

 

 

SECTION – B

 

Answer any FIVE questions.                                                                          (5 ´ 8 = 40 marks)

 

  1. Show that the distribution function is non-decreasing and right continuous.

 

  1. ‘n’ different letters are placed at random in ‘n’ different envelopes. Find the probability that none of the letters occupies the envelope corresponding to it.

 

  1. Show that correlation coefficient lies between -1 and 1. Also show that p2 = 1 is a necessary and sufficient condition for P [Y = a + bx] = 1 to hold.

 

  1. Derive the MGF of gamma distribution and obtain its mean and variance.

 

  1. Let f (x, y) = 2 0 < x < y < 1 the pdf of X and Y.  Obtain E [X | Y] and E [Y | X].  Also obtain the correlation coefficient between X and Y.

 

  1. Show that Binomial distribution tends to Poisson distribution under some conditions.

 

  1. State Chebyshw’s inequality. Prove Bernoulli’s weak law of large numbers.

 

  1. 4 distinct integers are chosen at random and without replacement from the first 10 positive integers. Let the random variable X be the next to the smallest of these 4 numbers.  Find the pdf of X.

 

 

SECTION – C

 

Answer any TWO questions                                                                          (2 ´ 20 = 40 marks)

 

  1. a) Let {An} be a decreasing sequence of events. Show that

P .  Deduce the result for increasing sequence.

 

  1. b) A box contains M white and N – M red balls. A sample of size n is drawn from the

box.  Obtain the probability distribution of the number of white balls if the sampling is

done     i) with replacement     ii) without replacement.                                       (10+10)

 

  1. a) State any five properties of Normal distribution.

 

  1. In a distribution exactly Normal 7% are under 35 and 89% are under 63. What are the mean and standard deviation of the distribution?
  2. If X1 and X2 are independent N and Nrespectively, obtain the distribution of a1 X 1 + a2 X2.                                                                                  (5+10+5)

 

  1. a) Show that M (t1, t2) = M (t1, 0) M (0, t2) “, t1, t2 is a necessary and sufficient condition

for the independence of X1 and X2.

 

  1. b) Let X1 and X2 be independent r.v’s with

f1 (x1) =  ,  0 < x1 < ¥

f2 (x2) =  ,  0 < x2 < ¥

Obtain the joint pdf of Y1 = X1 + X2 and Y2 =

Also obtain the marginal distribution of Y1 and Y2

 

  1. c) Suppose E (XY) = E (X) E (Y).  Does it imply X and Y are independent.

(6+10+4)

 

  1. a) State and prove Lindberg-Levy central limit theorem.

 

  1. b) Let Fn (x) be distribution function of the r.v Xn, n = 1,2,3… Show that the

sequence{Xn} is convergent in probability to O if and only if the sequence Fn (x)

satisfies

 

=   0     x < 0

1    x ≥ 0

 

  1. c) Let Xn, n = 1, 2, … be independent Poisson random variables. Let y100 = X1 + X2 + …+

X100.  Find  Pr [190 £ Y100 £ 210].                                                                        (8+8+4)

 

 

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Loyola College M.Sc. Mathematics Nov 2003 Mathematical Statistics – I Question Paper PDF Download

LOYOLA COLLEGE (AUTONOMOUS), CHENNAI –600 034

M.Sc., DEGREE EXAMINATION – MATHEMATICS

THIRD SEMESTER – NOVEMBER 2003

ST 3951 / S 972 – MATHEMATICAL STATISTICS – I

10.11.2003                                                                                                           Max:100 marks

1.00 – 4.00

SECTION-A

Answer ALL questions.                                                                                   (10×2=20 marks)

 

  1. Illustrate that pairwise independence does not imply mutual independence of random events.
  2. Prove that every distribution function is continuous atleast from the left.
  3. Show that if the probability of a random event equals zero, it does not follow that this event is impossible. Similarly prove that if the probability of a random event equals one, its does not follow that this event is sure.
  4. Define truncated distribution of a random variable X and given an example.
  5. Give two examples of random variables for which expected value does not exist.
  6. Define convergence in law of a sequence of random variables and give an example.
  7. Show that if the moment of order k of a random variable X exists, then

where a > 0.

  1. State the theorem of Bochner, giving necessary and sufficient conditions for a function to be a characteristic function.
  2. The characteristic function of the random variable X is given by = exp Find the density function of this random variable.
  3. State Lindeberg – Levy Central  Limit

 

SECTION-B

Answer any FIVE questions.                                                                           (5×8=40 marks)

 

  1. Let {An}, n =1, 2, ….., be a non increasing sequence of events and let A be their product. Then show that P (A) = .
  2. Show that the conditional probability satisfies the axioms of the theory of probability.
  3. a) State and prove Bayes
  4. b) Illustrate the application of Bayes
  5. State and prove a necessary and sufficient condition for the independence of the random variables X and Y of the discrete type.
  6. If a random variable has a symmetric distribution and its expected value exists, then show that this expected value equals the center of symmetry. Hence show that for a symmetric distribution the central moments of odd orders (if they exist) are equal to zero.
  7. a) If not all the moments exist, then show that those moments that do exists fail to determine the distribution function F (x).
  8. b) Define convergence in rth mean and given an example.
  9. The random variables X and Y have the joint density given by

f (x,y) = .   Compute the coefficient of correlation.

  1. Define the t, chi-square and F distributions.

 

SECTION-C

Answer any TWO questions.                                                                           (2×20=40 marks)

 

  1. a) State and prove Lapunov inequality concerning absolute moments.            (10)
  2. b) Show that the expected value of the product of an arbitrary finite number of

independent random variables, whose expected values exist, equals the product of the

expected values of these variables.                                                                              (4)

  1. c) Show that the covariance of two independent random variables equals zero. Is the

converse true?  Justify your answer.                                                                             (6)

  1. a) State and prove Levy Inversion Theorem concerning the determination of the

distribution function by the characteristic function.                                                   (14)

  1. b) Prove that the probability function of the Poisson distribution can be obtained as the

limit of a sequence of probability functions of the binomial distribution.                   (6)

  1. a) Show that for n ³ 2, the binomial distribution can be obtained from the zero-one

distribution.                                                                                                                   (4)

  1. b) Examine the additive property for Gamma random variables. (6)
  2. c) State and prove Bernoulli’s weak law of large numbers.                      (10)
  3. a) State and prove the Chebyshev Show that in the class of random variables

whose second order moment exists, one cannot obtain a better inequality than the

Chebyshev inequality.                                                                                                (10)

  1. b) If the th moment of a random variable exists, then show that can be expressed

in terms of the th derivative of the characteristic function of this random variable

at t = 0.                                                                                                                          (8)

  1. c) Define the strong law of large numbers. (2)

 

 

 

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Loyola College M.Sc. Mathematics April 2006 Mathematical Statistics – I Question Paper PDF Download

             LOYOLA COLLEGE (AUTONOMOUS), CHENNAI – 600 034

M.Sc. DEGREE EXAMINATION – MATHEMATICS

 

THIRD SEMESTER – APRIL 2006

                                               ST 3951 – MATHEMATICAL STATISTICS – I

 

 

Date & Time : 27-04-2006/1.00-4.00 P.M.   Dept. No.                                                       Max. : 100 Marks

 

 

     SECTION-A    (10 ´ 2 = 20)

Answer ALL questions.  Each question carries 2 marks.

  1. Give an example for a non-decreasing sequence of sets.
  1. Distinguish between experiment and random experiment.
  2. Let f (x) =    x/15,  x=1,2,3,4,5

0,  otherwise.

Find the median of the above distribution.

  1.  Let f(x) = (4-x) / 16, -2 < x < 2 ,zero elsewhere, be the p.d.f. of X.

If Y = ‌ X ‌ , compute P(Y ≤ 1).

  1. Give an example of a random variable in which mean doesn’t exist.
  1. Prove that E(E(X / Y)) = E(X).
  2. Define Hyper Geometric distribution.
  3. Define the characteristic function of a multidimensional random vector.

p                         p                                                 p

  1.  If    Xn → X    and    Yn →   Y, then show that Xn + Y →   X +Y.
  2. State Lindeberg-Feller theorem.

SECTION-B   (8 x 5 = 40)

Answer any 5 questions.  Each question carries 8 marks.

  1. Let f(x) = ½, -1 < x < 1, zero elsewhere, be the p.d.f. of X.  Find the distribution

function and the p.d.f. of Y = X2.

  1. State and prove Chebyshev’s inequality.
  2. If X1 and X2 are discrete random variables having the joint p.m.f.

f(x1,x2) = ( x1 + 2 x2 ) / 18,  (x1, x) = (1,1), (1,2), (2,1), (2,2), zero elsewhere, determine the conditional mean and variance of X2, given X1 =x1, for x1 = 1 or 2.

Also, compute E[ 3X1 – 2 X2 ].

  1. State and prove any two properties of MGF.
  2. Stating the conditions, show that binomial distribution tends to Poisson

distribution.

  1. Obtain the central moments of N (µ, σ2).
  2. Let X ~ G (n1, α) and Y ~ G (n2, α) be independent. Find the distribution of X/Y.
  3. Explain in detail the difference between WLLN and SLLN.

 

                                           SECTION-C ( 20 x 2 = 40 )

Answer any 2 questions. Each question carries 20 marks.

  1. a) State and prove Bayes’ theorem. (10)
  2. b) Bowl I contains 3 red chips and 7 blue chips. Bowl II contains 6 red chips and 4 blue chips. A bowl is selected at random and then 1 chip is drawn from this bowl.  Compute the probability that this chip is red.  Also, relative to the hypothesis that the chip is red, find the conditional probability that is drawn from bowl II.  (10)

 

  1. a) Find the mean and variance of the random variable X having the distribution function:

 

F(x)   =   0,        x < 0,

( x/4),   0≤x <1,

(x2 /4), 1≤x<2,

1 ,        x≥ 2.                                                  (10)

  1. b) Let X have the uniform distribution over the interval ( -π/2 , π/2). Find the

distribution of Y  = tan X.    (10)

 

  1. a) State and prove Kolmogorov’s strong law of large numbers. (12)
  2. b) State and prove Borel-Cantelli lemma. (8)

 

  1. a) Examine if central limit theorem (using Lyapounov’s condition) holds for the

following sequence of independent variates:

 

 

P     Xk   =   ±  2k      =   2-(2k + 1) ,             P       Xk  =  0    =   1 – 2–2k   (8)

 

  1. b) State and prove Lindeberg-Levy central limit theorem. (12)

 

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