1 / 9

Bayes Theorem

Bayes Theorem. Motivating Example: Drug Tests. A drug test gives a false positive 2% of the time (that is, 2% of those who test positive actually are not drug users) And the same test gives a false negative 1% of the time (that is, 1% of those who test negative actually are drug users)

dympna
Télécharger la présentation

Bayes Theorem

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript


  1. Bayes Theorem

  2. Motivating Example: Drug Tests A drug test gives a false positive 2% of the time (that is, 2% of those who test positive actually are not drug users) And the same test gives a false negative 1% of the time (that is, 1% of those who test negative actually are drug users) If Joe tests positive, what are the odds Joe is a drug user? Insufficient information! Suppose we know that 1% of the population uses the drug?

  3. Setting Up the Drug Test Problem Let T be the set of people who test positive Let D be the set of drug users These are events, and Pr(T|D) is the probability that a drug user tests positive Pr(T|D) = .99 because the false negative rate is 1%, that is, 99% of drug users test positive, 1% test negative We want to know: What is Pr(D|T)? This is a very different question: What is the probability you are a drug user, given that you test positive?

  4. Bayes Theorem Theorem: If Pr(A) and Pr(B) are both nonzero, Proof. We know that by the definition of conditional probability: and similarly for Pr(B|A). Then divide the left and right sides of (*) by Pr(B|A)∙Pr(B).

  5. Bayes, v. 2 This enables us to calculate Pr(A|B) using only the absolute probability Pr(A) and the conditional probabilities Pr(B|A) and Pr(B|¬A). Proof. We know that Now multiply by Pr(B|A) and rewrite Pr(B) using the law of total probability.

  6. Drug Test again • Suppose that a drug test has • 2% false positives (that is, 2% of the people who test positive are not drug users ) • 1% false negatives (1% of those who test negative are drug users). • Suppose 1% of the population uses drugs. If you test positive, what are the odds you are actually a drug user?

  7. Drug test, cont’d Let D = “Uses drugs” Let T = “Tests positive” What is Pr(D|T)?

  8. If you fail the drug test, there is only one chance in three you are actually a drug user! • How can this be? Think about it. • Out of 1000 people there are 10 drug users and 990 non-users. • Of those 990, 2% or almost 20 test positive. • Almost all of the 10 users also test positive. • So there are 2 non-users for every user, among those who test positive!

  9. FINIS

More Related