Cromwell's rule

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Cromwell's rule, named by statistician Dennis Lindley,[1] states that the use of prior probabilities of 1 ("the event will definitely occur") or 0 ("the event will definitely not occur") should be avoided, except when applied to statements that are logically true or false, such as 2+2 equaling 4.

The reference is to Oliver Cromwell, who wrote to the General Assembly of the Church of Scotland on 3 August 1650, shortly before the Battle of Dunbar, including a phrase that has become well known and frequently quoted:[2]

I beseech you, in the bowels of Christ, think it possible that you may be mistaken.

As Lindley puts it, assigning a probability should "leave a little probability for the moon being made of green cheese; it can be as small as 1 in a million, but have it there since otherwise an army of astronauts returning with samples of the said cheese will leave you unmoved."[3] Similarly, in assessing the likelihood that tossing a coin will result in either a head or a tail facing upwards, there is a possibility, albeit remote, that the coin will land on its edge and remain in that position.

If the prior probability assigned to a hypothesis is 0 or 1, then, by Bayes' theorem, the posterior probability (probability of the hypothesis, given the evidence) is forced to be 0 or 1 as well; no evidence, no matter how strong, could have any influence.

A strengthened version of Cromwell's rule, applying also to statements of arithmetic and logic, alters the first rule of probability, or the convexity rule, 0 ≤ Pr(A) ≤ 1, to 0 < Pr(A) < 1.

Bayesian divergence (pessimistic)[edit]

An example of Bayesian divergence of opinion is based on Appendix A of Sharon Bertsch McGrayne's 2011 book.[4] Tim and Susan disagree as to whether a stranger who has two fair coins and one unfair coin (one with heads on both sides) has tossed one of the two fair coins or the unfair one; the stranger has tossed one of his coins three times and it has come up heads each time.

Tim assumes that the stranger picked the coin randomly – i.e., assumes a prior probability distribution in which each coin had a 1/3 chance of being the one picked. Applying Bayesian inference, Tim then calculates an 80% probability that the result of three consecutive heads was achieved by using the unfair coin, because each of the fair coins had a 1/8 chance of giving three straight heads, while the unfair coin had an 8/8 chance; out of 24 equally likely possibilities for what could happen, 8 out of the 10 that agree with the observations came from the unfair coin. If more flips are conducted, each further head increases the probability that the coin is the unfair one. If no tail ever appears, this probability converges to 1. But if a tail ever occurs, the probability that the coin is unfair immediately goes to 0 and stays at 0 permanently.

Susan assumes the stranger chose a fair coin (so the prior probability that the tossed coin is the unfair coin is 0). Consequently, Susan calculates the probability that three (or any number of consecutive heads) were tossed with the unfair coin must be 0; if still more heads are thrown, Susan does not change her probability. Tim and Susan's probabilities do not converge as more and more heads are thrown.

Bayesian convergence (optimistic)[edit]

An example of Bayesian convergence of opinion is in Nate Silver's 2012 book The Signal and the Noise: Why so many predictions fail — but some don't.[5] After stating, "Absolutely nothing useful is realized when one person who holds that there is a 0 (zero) percent probability of something argues against another person who holds that the probability is 100 percent", Silver describes a simulation where three investors start out with initial guesses of 10%, 50% and 90% that the stock market is in a bull market; by the end of the simulation (shown in a graph), "all of the investors conclude they are in a bull market with almost (although not exactly of course) 100 percent certainty."

See also[edit]

References[edit]

  1. ^ Jackman, Simon (2009) Bayesian Analysis for the Social Sciences, Wiley. ISBN 978-0-470-01154-6 (ebook ISBN 978-0-470-68663-8).
  2. ^ Cromwell, Oliver (1650): Letter 129
  3. ^ Lindley, Dennis (1991). Making Decisions (2 ed.). Wiley. p. 104. ISBN 0-471-90808-8.
  4. ^ McGrayne, Sharon Bertsch. (2011). The Theory That Would Not Die: How Bayes' Rule Cracked The Enigma Code, Hunted Down Russian Submarines, & Emerged Triumphant from Two Centuries of Controversy. New Haven: Yale University Press. ISBN 9780300169690; OCLC 670481486 The Theory That Would Not Die, pages 263-265 at Google Books
  5. ^ Silver, Nate (2012). The Signal and the Noise: Why so many predictions fail -- but some don't. New York: Penguin. pp. 258–261. ISBN 978-1-59-420411-1.