Lecture Notes (Italics = Handouts)

Lecture Notes (Italics = Handouts)

Chapters 12 (Moore)

Binomial Distributions

Random variables were introduced in the text in chapter 9 (pages 176-177). I didn’t need them to now so I saved them up.

Random Variables

A random variable assigns to each element of a sample space a unique numerical value. We use uppercase italicized letters (e.g. X, Y) to denote random variables and lowercase italicized letters (e.g. x, y) to denote values of a random variable.

(3 coins, 3 M/C questions, two dice, randomly select a student from the class)

discrete vs continuous (usually count vs measure)

(e.g. on students: ht, wt, # sibling, distance from home to SCC, household income, # in household, ZIP code, units completed)

Discrete probability distributions (can be given by a table, formula, or a probability histogram)

For example: by table:

x / P(x)
–3 / 0.2
–1 / 0.4
2 / 0.3
5 / 0.1

by formula,

P(x) = x/10 for x = 1, 2, 3, 4

Properties: 0 £ P(x) £ 1 and ΣP(x) = 1

Mean and Standard Deviation of a discrete probability distribution

Mean and Variance of Discrete Random Variables (Moore)

Binomial Probability Distributions

Bernoulli experiment (exactly two outcomes, generically “success” and “failure”, probability of success is denoted by p)

Binomial Model

Binomial experiment, n independent, identical Bernoulli trials

If X is the number of successes for a binomial experiment we then X has a binomial probability distribution with n trial and the probability of a success = p and we write X ~ Binom(n, p), (note that the probability of a failure is denoted by q = 1 – p)

Probability for binomial distributions (Binomial Distributions)

formula P(X = k) = nCk pk qn–k, where

table (rare now)

by calculator

For X ~ Binom(n, p) on the TI calculators

P(X = k) = binompdf(n,p,k)

P(X £ k) = binomcdf(n,p,k)

P(X ≥ k) = 1 – binomcdf(n,p,k–1)

by computer (Maple, Excel, etc.)

Mean and standard deviation of a binomial distribution

m = np s =

Note: for np ³ 10 and nq ³ 10 binomial approximately normal (see Minitab Histograms)

Back in the mid-20th century (before modern calculators and computer programs) it was common to use the fact the binomial distribution, Binom(n, p) when np ³ 10 and nq ³ 10 can be closely approximated by the Normal distribution N(np, ) to approximate binomial probabilities. This is covered in the book on pages 223 – 224, you can read it for historical purposes but you won’t be tested on it.

Chapter 12 Exercises: 1 – 5, 7, 9, 12 – 19, 24 plus the handout “Binomial Distributions”

Go to Chapter 18.