Applied statistics/Tutorials: Difference between revisions
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:::: = 1 x (1/1000)/(1/20) - which is 0.02, or 2%. | :::: = 1 x (1/1000)/(1/20) - which is 0.02, or 2%. | ||
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==The Sally Clark Case== | |||
Sally Clark was convicted of murdering her two babies on the evidence of an eminent pathologist who had abvised the jury that there was only one chance in 73 million that they had died from natural causes - a figure obtained by squaring the probability of a single death by natural causes. Subseqent evidence revealed a common cause - a possibility that was not condidered at the first trial. <ref>[http://www.rss.org.uk/PDF/RSS%20Statement%20regarding%20statistical%20issues%20in%20the%20Sally%20Clark%20case,%20October%2023rd%202001.pdf ''..Issues Raised in the Sally Clark Case'', News release by the Royal Statistical Society, 23 October 2000]</ref> | |||
==References== | |||
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Revision as of 12:28, 29 June 2009
Rules of chance
The addition rule
For two mutually exclusive events, A and B,
the probability that either A or B will occur is equal to the probability that A will occur plus the probability that B will occur,
- P(A or B) = P(A) + P(B).
The multiplication rule
For two independent (unrelated) events, A and B,
the probability that A and B will both occur is equal to the probability that A will occur multiplied by the probability that B will occur,
- P(A and B) = P(A) x P(B)
Bayes' theorem
The probability that event A will occur, given that event B has occurred is equal to the probability that B will occur, given that A has occurred, mutiplied by the probability that A will occur divided by the probability that B will occur,
- P(A/B) = P(B/A) x P(A)/P(B).
The false positive question
The question:
If a test of a disease that has a prevalence rate of 1 in 1000 has a false positive rate of 5%, what is the chance that a person who has been given a positive result actually has the disease.
The answer:
2%
Proof:
Let A denote the event of having the disease and, B the event of having been tested positive (for the purpose of applying Bayes'theorem),
Then P(B/A) which is the probability of having been tested positive when having the disease, can be taken as equal to 1;
And P(A) is the probability of having the disease, which with a prevalence of 1 in 1000 must be equal to 1/1000<
And P(B) is the probability of being tested positive, which can be arrived at by 3 steps:
Step 1 is to observe that since the prevalence of the disease is 1 in 1000, 999 persons out of every 1000 are healthy.
Step 2 is to recall that for each healthy person the probability of being tested positive is 5% or 1 in 20.
Step 3 is to apply the multiplication rule and get the answer:
- P(B) = 999/1000 multiplied by 1/20 or, near enough 1/20.
- P(B) = 999/1000 multiplied by 1/20 or, near enough 1/20.
So applying Bayes' theorem, the probability of having the disease, given that you have been tested positive is given by
- P(A/B) = P(B/A) x P(A)/P(B), or:
- = 1 x (1/1000)/(1/20) - which is 0.02, or 2%.
- P(A/B) = P(B/A) x P(A)/P(B), or:
The Sally Clark Case
Sally Clark was convicted of murdering her two babies on the evidence of an eminent pathologist who had abvised the jury that there was only one chance in 73 million that they had died from natural causes - a figure obtained by squaring the probability of a single death by natural causes. Subseqent evidence revealed a common cause - a possibility that was not condidered at the first trial. [1]