Presentation is loading. Please wait.

Presentation is loading. Please wait.

Section 10.5 Let X be any random variable with (finite) mean  and (finite) variance  2. We shall assume X is a continuous type random variable with p.d.f.

Published byBrandon Fleming Modified over 8 years ago

Similar presentations

Presentation on theme: "Section 10.5 Let X be any random variable with (finite) mean  and (finite) variance  2. We shall assume X is a continuous type random variable with p.d.f."— Presentation transcript:

1 Section 10.5 Let X be any random variable with (finite) mean  and (finite) variance  2. We shall assume X is a continuous type random variable with p.d.f. f(x), but what follows applies to a discrete type random variable where integral signs are replaced by summation signs and the p.d.f. is replaced by a p.m.f. For any k  1, we observe that  2 = E[(X –  ) 2 ] = –   (x –  ) 2 f(x) dx = {x : |x –  |  k  } (x –  ) 2 f(x) dx + {x : |x –  | < k  } (x –  ) 2 f(x) dx  {x : |x –  |  k  } (x –  ) 2 f(x) dx  {x : |x –  |  k  } k 2  2 f(x) dx = {x : |x –  |  k  } k 2  2 f(x) dx

2 We now have that  2  k 2  2 P(|X –  |  k  ) which implies that 1 P(|X –  |  k  )  — k 2 This is Chebyshev’s inequality and is stated in Theorem 10.5-1. We may also write 1 P(|X –  | < k  )  1 – — k 2

3 1. (a) (b) (c) Let X be a random selection from one of the first 9 positive integers. Find the mean and variance of X.  = E(X) =  2 = Var(X) = 5 20 — 3 Find P(|X – 5|  4). If Y is any random variable with the same mean and variance as X, find the upper bound on P(|Y – 5|  4) that we get from Chebyshev’s inequality. P(|X – 5|  4) =P(X = 1  X = 9) = 2 — 9 P(|Y – 5|  4) =P[|Y – 5|  4(3/20) 1/2 (20/3) 1/2 ]  20/3 5 —— =— 1612 k 

4 2. (a) (b) Let X be a random variable with mean 100 and variance 75. Find the lower bound on P(|X – 100| < 10) that we get from Chebyshev’s inequality. P(|X – 100| < 10) = P[|X – 100| < (2/  3)(5  3)]  1 1 – ——– = (2/  3) 2 Find what the value of P(|X – 100| < 10) would be, if X had a U(85, 115) distribution. 1 — 4 P(|X – 100| < 10) = 20 — = 30 P(90 < X < 110) = 2 — 3 k 

5 3. (a) (b) Let Y have a b(n, 0.75) distribution. Find the lower bound on P(|Y / n – 0.75| < 0.05) that we get from Chebyshev’s inequality when n = 12. Find the exact value of P(|Y / n – 0.75| < 0.05) when n = 12. When n = 12, E(Y) =, and Var(Y) =, and92.25 P(|Y / n – 0.75| < 0.05) =P(|Y – 9| < 0.6) = P[|Y – 9| < (0.4)(1.5)]  (A lower bound cannot be found, since 0.4 < 1.) When n = 12, P(|Y / n – 0.75| < 0.05) = P(|Y – 9| < 0.6) = P(Y = 9) =0.6488 – 0.3907 = 0.2581

6 (c) (d) Find the lower bound on P(|Y / n – 0.75| < 0.05) that we get from Chebyshev’s inequality when n = 300. By using the normal approximation, show that when n = 300, then P(|Y / n – 0.75| < 0.05) = 0.9464. When n = 300, E(Y) =, and Var(Y) =, and22556.25 P(|Y / n – 0.75| < 0.05) =P(|Y – 225| < 15) = P[|Y – 225| < (2)(7.5)]  1 1 – — = 0.75 2 2

Download ppt "Section 10.5 Let X be any random variable with (finite) mean  and (finite) variance  2. We shall assume X is a continuous type random variable with p.d.f."

Similar presentations

Discrete Uniform Distribution

Discrete Uniform Distribution
1. (a) (b) The random variables X 1 and X 2 are independent, and each has p.m.f.f(x) = (x + 2) / 6 if x = –1, 0, 1. Find E(X 1 + X 2 ). E(X 1 ) = E(X 2.

1. (a) (b) The random variables X 1 and X 2 are independent, and each has p.m.f.f(x) = (x + 2) / 6 if x = –1, 0, 1. Find E(X 1 + X 2 ). E(X 1 ) = E(X 2.
Independence of random variables

Independence of random variables
Probability Theory STAT 312 STAT 312 Dr. Zakeia AlSaiary.

Probability Theory STAT 312 STAT 312 Dr. Zakeia AlSaiary.
Probability Theory Part 2: Random Variables. Random Variables  The Notion of a Random Variable The outcome is not always a number Assign a numerical.

Probability Theory Part 2: Random Variables. Random Variables  The Notion of a Random Variable The outcome is not always a number Assign a numerical.
Section 2.6 Consider a random variable X = the number of occurrences in a “unit” interval. Let = E(X) = expected number of occurrences in a “unit” interval.

Section 2.6 Consider a random variable X = the number of occurrences in a “unit” interval. Let = E(X) = expected number of occurrences in a “unit” interval.
Section 5.7 Suppose X 1, X 2, …, X n is a random sample from a Bernoulli distribution with success probability p. Then Y = X 1 + X 2 + … + X n has a distribution.

Section 5.7 Suppose X 1, X 2, …, X n is a random sample from a Bernoulli distribution with success probability p. Then Y = X 1 + X 2 + … + X n has a distribution.
Prof. Bart Selman Module Probability --- Part d)

Prof. Bart Selman Module Probability --- Part d)
Section 5.3 Suppose X 1, X 2, …, X n are independent random variables (which may be either of the discrete type or of the continuous type) each from the.

Section 5.3 Suppose X 1, X 2, …, X n are independent random variables (which may be either of the discrete type or of the continuous type) each from the.
Chapter 9 Mathematical Preliminaries. Stirling’s Approximation Fig. 9.2-1 by trapezoid rule take antilogs Fig. 9.2-2 by midpoint formula take antilogs.

Chapter 9 Mathematical Preliminaries. Stirling’s Approximation Fig by trapezoid rule take antilogs Fig by midpoint formula take antilogs.
Section 8.3 Suppose X 1, X 2,..., X n are a random sample from a distribution defined by the p.d.f. f(x)for a < x < b and corresponding distribution function.

Section 8.3 Suppose X 1, X 2,..., X n are a random sample from a distribution defined by the p.d.f. f(x)for a < x < b and corresponding distribution function.
Sections 4.1, 4.2, 4.3 Important Definitions in the Text:

Sections 4.1, 4.2, 4.3 Important Definitions in the Text:
CONTINUOUS RANDOM VARIABLES. Continuous random variables have values in a “continuum” of real numbers Examples -- X = How far you will hit a golf ball.

CONTINUOUS RANDOM VARIABLES. Continuous random variables have values in a “continuum” of real numbers Examples -- X = How far you will hit a golf ball.
Section 3.3 If the space of a random variable X consists of discrete points, then X is said to be a random variable of the discrete type. If the space.

Section 3.3 If the space of a random variable X consists of discrete points, then X is said to be a random variable of the discrete type. If the space.
Section 10.6 Recall from calculus: lim= lim= lim= x  y  1 1 + — x x 1 1 + — x kx k 1 + — y y eekek (Let y = kx in the previous limit.) ekek If derivatives.

Section 10.6 Recall from calculus: lim= lim= lim= x  y  — x x — x kx k 1 + — y y eekek (Let y = kx in the previous limit.) ekek If derivatives.
Lesson #13 The Binomial Distribution. If X follows a Binomial distribution, with parameters n and p, we use the notation X ~ B(n, p) p x (1-p) (n-x) f(x)

Lesson #13 The Binomial Distribution. If X follows a Binomial distribution, with parameters n and p, we use the notation X ~ B(n, p) p x (1-p) (n-x) f(x)
1 Sampling Distribution Theory ch6. 2  Two independent R.V.s have the joint p.m.f. = the product of individual p.m.f.s.  Ex6.1-1: X1is the number of.

1 Sampling Distribution Theory ch6. 2  Two independent R.V.s have the joint p.m.f. = the product of individual p.m.f.s.  Ex6.1-1: X1is the number of.
Section 5.6 Important Theorem in the Text: The Central Limit TheoremTheorem 5.6-1 1. (a) Let X 1, X 2, …, X n be a random sample from a U(–2, 3) distribution.

Section 5.6 Important Theorem in the Text: The Central Limit TheoremTheorem (a) Let X 1, X 2, …, X n be a random sample from a U(–2, 3) distribution.
Copyright © Cengage Learning. All rights reserved. 4 Continuous Random Variables and Probability Distributions.

Copyright © Cengage Learning. All rights reserved. 4 Continuous Random Variables and Probability Distributions.
Chapter 21 Random Variables Discrete: Bernoulli, Binomial, Geometric, Poisson Continuous: Uniform, Exponential, Gamma, Normal Expectation & Variance, Joint.

Chapter 21 Random Variables Discrete: Bernoulli, Binomial, Geometric, Poisson Continuous: Uniform, Exponential, Gamma, Normal Expectation & Variance, Joint.

Similar presentations

Ads by Google