Functions of Random Variables
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Transcript of Functions of Random Variables
Functions of Random VariablesNotes of STAT 6205 by Dr. Fan
6205-Ch5 2
Overview• Chapter 5• Functions of One random variable
o General: distribution function approacho Change-of-variable approach
• Functions of Two random variableso Change-of-variable approach
• Functions of Independent random variables• Order statistics• The Moment Generating Function approach• Random functions associated with normal distributions
o Student’s t-distribution• The Central Limit Theorem
o Normal approximation of binomial distribution• (Section 10.5) Chebyshev’s Inequality and convergence in
probability
6205-Ch5 3
General Method:Distribution Function
Approach • Goal: to find the distribution of Y=h(X)
• When: the pdf of X, f(x) is known
• Then the cdf of Y, G(y) is:
• And the pdf of Y, g(y)=G’(y)
yxh
dxxfyXhPyYPyG)(
)(])([][)(
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Examples/Exercises• Let X~U(0,10) and Y=X^3. Find the cdf and pdf of
Y
• Let X~Exp(mu=2) and Y=Exp(X). Find the cdf and pdf of Y
• Let X~Gamma(a,b) and X=log(Y). Find the pdf of Y (Loggamma distribution)
6205-Ch5 5
Change of Variable Approach
• When: the pdf of X is known and Y=h(X), a monotonic function (i.e. its inverse function exists; X = V(Y) )
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Examples/ExercisesLet Y=(1-X)^3 and find its pdf g(y)
• Problem 1: f(x)=x/2, 0<x<2
• Problem 2: f(x)=3(1-x)^2, 0<x<1
• Problem 3: verify that the g attained in problem 2 is a proper pdf
• Problem4: revisit the problems in Slide 4
6205-Ch5 7
Transformations of Two Random Variables
• Let f(x1,x2) be the joint pdf of X1,X2• Let Y1=u1(X1,X2) and Y2=u2(X1,X2) • where u1, u2 have inverse functions, that is, X1=v1(Y1,Y2)
and X2=v2(Y1,Y2)• Goal: find the joint pdf of Y1,Y2, g(y1,y2)
.
yx
yx
yx
yx
JJacobian theand
),( where)],,(),,([||),(
2
2
1
2
2
1
1
1
12121221121
SyyyyvyyvfJyyg
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Examples/Exercises1. f(x1,x2)=2 where 0<x1<x2<1; Y1=X1/X2 and Y2=X2
2. X1, X2 are independent exp(1) variables; Y1=X1-X2 and Y2=X1+X23. Reading: Examples 5.2-3, 4
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Independent Random Variables
• Let X1, X2, …,Xn be independent random variables
• Joint pmf (or pdf) of X1, X2, …, Xn:
f(x1,x2,…,xn)=f1(x1)f2(x2)…fn(xn)
• Random sample from a distribution f(x): X1, X2, … Xn are independent and identically
distributed; f(x1,x2,…,xn)=f(x1)f(x2)…f(xn)
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Examples/Exercises• Let X1, X2, …, Xn be a random sample from
Exp(0.5). Find the joint p.d.f of this sample.
• Exercise: What is the probability of seeing at least one Xi less than one? Exactly one less than one?
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Functions of Independent R. V.s
Theorem 5.3-2Let X1, X2, …, Xn be independent r. v.s. Then:
Theorem 5.3-3 (page 238)i
iinn XuEXuXuXuE )]([)]()...()([ 2211
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Examples/Exercises• Given a random sample of size n from a
distribution with mean mu and SD sigma, find the mean and variance of the sample mean
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Moment Generating Function
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Examples/Exercises• Example: Prove that the sum of i.i.d. Ber(p) r.v.s is
a Bin(n, p) r. v.
• Exercise: Prove that the sum of i.i.d. Exp(mu) r. v.s is a Gamma(a=n, b=0.5) r. v.
1) What is the m.g.f. of Exp(mu)?2) What is the m.g.f. of Gamma(a,b)?3) Prove this problem using m.g.f.
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Random Variables Assoc. With Normal Distributions
Theorem 1: The distribution of the sum of i.i.d. normal r.
v.s is also normal
Theorem 2: The distribution of the sum of normal r. v.s is also normal
Theorem 3: The distribution of the average of normal r.
v.s is also normal
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Student’s t-distribution
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Proof:1) Show S^2 and X-bar are independent2) Use m.g.f to prove the distribution is chi-square
Example: Show that the one-sample t test statistic is t-distributed with (n-1) degree of freedom
)1(~/
ntnS
XT
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Features of t distribution t(r)
• Shape:Bell-shaped
• Center and Spread:mean=0 if r > 1variance =r/(r-2) if r > 2 (undefined otherwise)
• M.G.F. does not exist
• Asymptotic distribution: (show simulation results)As d.f. r goes to infinity, t(r) approaches to N(0,1)
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Central Limit Theorem
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Examples/Exercises• Illustration: Bin(n, p) goes to Normal as n goes to infinity
[Aplia: STAT 1000 homework 4 Q3]
• Problem: Let X-bar be the mean of a random sample of n=25 currents in a strip of wire in which each measurement has a mean of 15 and a variance of 4. Estimate the probability of X-bar falling between 14.4 and 15.6.
• Problem: Suppose BART wants to perform some quality control. They know the waiting time for one at a BART station is U(10,30). In a random sample of 30 people, what tis the (approximate) probability that the average waiting time is more than 22 minutes? Recall the mean and variance for U(10,30) is 20 and 33.33 respectively.
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Chebyshev’s InequalityIf the r. v. X has a mean m and variance s^2, then for every k > 1,
Q: how to use this inequality to set up a lower bound of P(|X - m|< ks)?
Example: Use this inequality to find a lower bound of the probability that X is no more than 2 S.D. from the mean. Is the lower bound close to the exact probability if X ~ N( m, s^2 )
2/1)|(| kkXP
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Example: Tossing a CoinIf we want to estimate p, the chance of heads for a given coin, how many times share we toss it in order to get a sufficient accurate estimate?
Let Y be the # of heads on n flips; sample estimate of p, p-hat = Y/n. Use the Chebyshev’s Inequality to find the required sample size n.
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(Weak) Law of Large Number
Let X1, X2, …, Xn be i.i.d. r. v.s with finite mean m and finite S.D. s. Then X-bar converges to m in probability.
Proof. By Chebychev’s Inequality.