MAT 312
. . . PENNIES for the AGES. . .
Push the “Sample More Data” button on the screen and read the average age of a sample of 64 pennies taken from the jar.
Note the horizontal and vertical scales on the grid here and then record that (rounded) average age using properly scaled X.
Tuesday, April 22, 2014
MAT 312
Prob & Stat (MAT 312)Dr. Day Tuesday April 22, 2014
Grab 64 Pennies at Random then Plot Average Age
Simulations Review
Probability Distributions: Sample Spaces & Random Variables
Revisit: Normal Distributions
Collect Assignment #9
Tuesday, April 22, 2014
MAT 312
Probability Simulations
Simulations provide a means for calculating probabilities in situations where time, money, risk of injury, or other factors compel us to NOT carry out a real-life experiment of the situation.
Tuesday, April 22, 2014
Tuesday, April 22, 2014 MAT 312
MAT 312Tuesday, April 22, 2014
MAT 312
Probability Distributions
A probability distribution describes all possible outcomes of a probabilistic situation together with the probability associated with each outcome.
When the set of outcomes is described numerically, we call those outcomes random variables.
Tuesday, April 22, 2014
MAT 312
Probability Distributions
The mean or expected value of a probability distribution is the long-run average value of the outcome of a probabilistic situation; if X is a random variable with values a(1), a(2), . . . , a(n) and associated probabilities p(1), p(2), p(3). . . , p(n), then the expected value of X is:
E(X) = a(1)*p(1)+ a(2)*p(2) + . . . + a(n)*p(n).
Tuesday, April 22, 2014
MAT 312
Probability Distributions
The variance of a probability distribution is a measure of the spread of the distribution; if the values of a random variable X are a(1), a(2), . . . , a(n), with associated probabilities p(1), p(2), p(3). . . , p(n), then the variance of the random variable X is:
V(X) = var(X) =
(a(1)-E(X))2*p(1) + (a(2)-E(X))2*p(2) + . . . + (a(n)-E(X))2*p(n).
Note that the standard deviation of a distribution is just the square root of its variance.Tuesday, April 22, 2014
MAT 312
Common Probability Distributi
onsUniform Distributions: Probability distributions for which every outcome is equally likely.
Outcomes for a single roll of one fair die form a uniform distribution.
Tuesday, April 22, 2014
MAT 312
Common Probability Distributi
onsBinomial Distributions: Probability distributions for which all four of the following properties are true:
1) There are exactly two outcomes to each trial, typically referred to as success and failure.
2) The total number of trials is fixed in advance.
3) The outcomes from trial to trial are independent of each other.
4) The probability of success is the same from trial to trial.
Tuesday, April 22, 2014
MAT 312
Binomial Distributions
Examples
Flipping a fair coin 20 times and recording each outcome as heads or tails.
Rolling a die 10 times and recording each result as 6 or not 6.
Grabbing, with replacement, a block from a bag of blocks and recording that the block is green or not green. Repeat 100 times.
Tuesday, April 22, 2014
MAT 312
Common Probability Distributi
onsNormal Distributions: Continuous probability distributions that are symmetric and mound shaped, characterized with a mean (μ) and a standard deviation (σ).
Many phenomena can be represented using a normal distribution.Tuesday, April 22, 2014
MAT 312
Terms, Symbols, & Properties
outcomes: the possible results of an experiment
equally likely outcomes: a set of outcomes that each have the same likelihood of occurring
sample space: the set of all possible outcomes to an experiment
uniform sample space: a sample space filled with equally likely outcomes
non-uniform sample space: a sample space that contains two or more outcomes that are not equally likely
event: a collection of one or more elements from a sample space
Tuesday, April 22, 2014
MAT 312
expected value: the long-run average value of the outcome of a probabilistic situation; if an experiment has n outcomes with values a(1), a(2), . . . , a(n), with associated probabilities p(1), p(2), p(3). . . , p(n), then the expected value of the experiment is
a(1)*p(1)+ a(2)*p(2) + . . . + a(n)*p(n).
random event: an experimental event that has no outside factors or conditions imposed upon it.
P(A): represents the probability P for some event A.
probability limits: For any event A, it must be that P(A) is between 0 and 1 inclusive.
probabilities of certain or impossible events: An event B certain to occur has P(B) = 1, and an event C that is impossible has P(C) = 0.
Tuesday, April 22, 2014
MAT 312
complementary events: two events whose probabilities sum to 1 and that share no common outcomes. If A and B are complementary events, then P(A) + P(B) = 1.
mutually exclusive events: two events that share no outcomes. If events C and D are mutually exclusive, then
P(C or D) = P(C) + P(D)
If two events are not mutually exclusive, thenP(C or D) = P(C) + P(D) − P(C and D).
independent events: two events whose outcomes have no influence on each other. If E and F are independent events, then
P(E and F) = P(E) * P(F)
Tuesday, April 22, 2014
MAT 312
conditional probability: the determination of the probability of an event taking into account that some condition may affect the outcomes to be considered. The symbol P(A|B) represents the conditional probability of event A given that event B has occurred. Conditional probability is calculated as
P(A|B) = P(A and B)/P(B)
geometrical probability: the determination of probability based on the use of a 1-, 2-, or 3-dimensional geometric model.
Tuesday, April 22, 2014
MAT 312
(C) Fritz wants to collect all 6 superhero figures contained in boxes of Whamo! cereal. Each specially marked box of cereal contains one superhero, randomly distributed into those boxes.
Create, describe, execute, and summarize the results for a simulation to answer the following question. For consistency, we each should conduct 20 trials.
How many boxes will Fritz have to purchase to collect a full set of 6 superheros?
Provide simulation details as modeled in class using our 5-step simulation process.
Tuesday, April 22, 2014
Assignment #9 (due Thursday
4/24/14)
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