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In
probability theory Probability theory is the branch of mathematics concerned with probability. Although there are several different probability interpretations, probability theory treats the concept in a rigorous mathematical manner by expressing it through a set ...
, the rule of succession is a formula introduced in the 18th century by
Pierre-Simon Laplace Pierre-Simon, marquis de Laplace (; ; 23 March 1749 – 5 March 1827) was a French scholar and polymath whose work was important to the development of engineering, mathematics, statistics, physics, astronomy, and philosophy. He summarized ...
in the course of treating the
sunrise problem The sunrise problem can be expressed as follows: "What is the probability that the sun will rise tomorrow?" The sunrise problem illustrates the difficulty of using probability theory when evaluating the plausibility of statements or beliefs. Acc ...
. The formula is still used, particularly to estimate underlying probabilities when there are few observations or for events that have not been observed to occur at all in (finite) sample data.


Statement of the rule of succession

If we repeat an experiment that we know can result in a success or failure, ''n'' times independently, and get ''s'' successes, and ''n − s'' failures, then what is the probability that the next repetition will succeed? More abstractly: If ''X''1, ..., ''X''''n''+1 are
conditionally independent In probability theory, conditional independence describes situations wherein an observation is irrelevant or redundant when evaluating the certainty of a hypothesis. Conditional independence is usually formulated in terms of conditional probabi ...
random variables that each can assume the value 0 or 1, then, if we know nothing more about them, :P(X_=1 \mid X_1+\cdots+X_n=s)=.


Interpretation

Since we have the prior knowledge that we are looking at an experiment for which both success and failure are possible, our estimate is as if we had observed one success and one failure for sure before we even started the experiments. In a sense we made ''n'' + 2 observations (known as
pseudocount In statistics, additive smoothing, also called Laplace smoothing or Lidstone smoothing, is a technique used to smooth categorical data. Given a set of observation counts \textstyle from a \textstyle -dimensional multinomial distribution wit ...
s) with ''s ''+ 1 successes. Although this may seem the simplest and most reasonable assumption, which also happens to be true, it still requires a proof. Indeed, assuming a pseudocount of one per possibility is one way to generalise the binary result, but has unexpected consequences — see Generalization to any number of possibilities, below. Nevertheless, if we had not known from the start that both success and failure are possible, then we would have had to assign :P'(X_=1 \mid X_1+\cdots+X_n=s)=. But see Mathematical details, below, for an analysis of its validity. In particular it is not valid when s=0, or s=n. If the number of observations increases, P and P' get more and more similar, which is intuitively clear: the more data we have, the less importance should be assigned to our prior information.


Historical application to the sunrise problem

Laplace used the rule of succession to calculate the probability that the Sun will rise tomorrow, given that it has risen every day for the past 5000 years. One obtains a very large factor of approximately 5000 × 365.25, which gives odds of about 1,826,200 to 1 in favour of the Sun rising tomorrow. However, as the mathematical details below show, the basic assumption for using the rule of succession would be that we have no prior knowledge about the question whether the Sun will or will not rise tomorrow, except that it can do either. This is not the case for sunrises. Laplace knew this well, and he wrote to conclude the sunrise example: "But this number is far greater for him who, seeing in the totality of phenomena the principle regulating the days and seasons, realizes that nothing at the present moment can arrest the course of it."Part II Section 18.6 of Jaynes, E. T. & Bretthorst, G. L. (2003). ''Probability Theory: The Logic of Science.'' Cambridge University Press. Yet Laplace was ridiculed for this calculation; his opponents gave no heed to that sentence, or failed to understand its importance. In the 1940s, Rudolf Carnap investigated a probability-based theory of inductive reasoning, and developed measures of degree of confirmation, which he considered as alternatives to Laplace's rule of succession. See also New riddle of induction#Carnap.


Mathematical details

The proportion ''p'' is assigned a uniform distribution to describe the uncertainty about its true value. (This proportion is not random, but uncertain. We assign a probability distribution to ''p'' to express our uncertainty, not to attribute randomness to ''p''. But this amounts, mathematically, to the same thing as treating ''p as if'' it were random). Let ''X''''i'' be 1 if we observe a "success" on the ''i''th
trial In law, a trial is a coming together of parties to a dispute, to present information (in the form of evidence) in a tribunal, a formal setting with the authority to adjudicate claims or disputes. One form of tribunal is a court. The tribunal ...
, otherwise 0, with probability ''p'' of success on each trial. Thus each ''X'' is 0 or 1; each ''X'' has a
Bernoulli distribution In probability theory and statistics, the Bernoulli distribution, named after Swiss mathematician Jacob Bernoulli,James Victor Uspensky: ''Introduction to Mathematical Probability'', McGraw-Hill, New York 1937, page 45 is the discrete probabi ...
. Suppose these ''X''s are
conditionally independent In probability theory, conditional independence describes situations wherein an observation is irrelevant or redundant when evaluating the certainty of a hypothesis. Conditional independence is usually formulated in terms of conditional probabi ...
given ''p''. We can use Bayes' theorem to find the conditional probability distribution of ''p'' given the data ''X''''i'', ''i'' = 1, ..., ''n.'' For the " prior" (i.e., marginal) probability measure of ''p'' we assigned a uniform distribution over the open interval ''(0,1)'' :f(p) = \begin 0 & \textp \le 0 \\ 1 & \text0 < p < 1 \\ 0 & \textp \ge 1 \end For the likelihood of a given ''p'' under our observations, we use the
likelihood function The likelihood function (often simply called the likelihood) represents the probability of random variable realizations conditional on particular values of the statistical parameters. Thus, when evaluated on a given sample, the likelihood funct ...
:L(p)=P(X_1=x_1, \ldots, X_n=x_n \mid p)=\prod_^n p^(1-p)^=p^s (1-p)^ where ''s'' = ''x''1 + ... + ''x''''n'' is the number of "successes" and ''n'' is the number of trials (we are using capital ''X'' to denote a random variable and lower-case ''x'' as the data actually observed). Putting it all together, we can calculate the posterior: :f(p \mid X_1=x_1, \ldots, X_n=x_n) = = To get the
normalizing constant The concept of a normalizing constant arises in probability theory and a variety of other areas of mathematics. The normalizing constant is used to reduce any probability function to a probability density function with total probability of one. ...
, we find :\int_0^1 r^s(1-r)^\,dr= (see
beta function In mathematics, the beta function, also called the Euler integral of the first kind, is a special function that is closely related to the gamma function and to binomial coefficients. It is defined by the integral : \Beta(z_1,z_2) = \int_0^1 t^( ...
for more on integrals of this form). The posterior probability density function is therefore :f(p \mid X_1=x_1, \ldots, X_n=x_n)=p^s(1-p)^. This is a
beta distribution In probability theory and statistics, the beta distribution is a family of continuous probability distributions defined on the interval , 1in terms of two positive parameters, denoted by ''alpha'' (''α'') and ''beta'' (''β''), that appear as ...
with expected value ::\operatorname(p \mid X_i=x_i\texti=1,\dots,n) = \int_0^1 p f(p \mid X_1=x_1, \ldots, X_n=x_n)\,dp = . Since ''p'' tells us the probability of success in any experiment, and each experiment is
conditionally independent In probability theory, conditional independence describes situations wherein an observation is irrelevant or redundant when evaluating the certainty of a hypothesis. Conditional independence is usually formulated in terms of conditional probabi ...
, the conditional probability for success in the next experiment is just ''p''. As ''p'' is being treated as if it is a random variable, the
law of total probability In probability theory, the law (or formula) of total probability is a fundamental rule relating marginal probabilities to conditional probabilities. It expresses the total probability of an outcome which can be realized via several distinct eve ...
tells us that the expected probability of success in the next experiment is just the expected value of ''p''. Since ''p'' is conditional on the observed data ''X''''i'' for ''i'' = 1, ..., ''n'', we have :P(X_=1 \mid X_i=x_i\texti=1,\dots,n)=\operatorname(p \mid X_i=x_i\texti=1,\dots,n)=. The same calculation can be performed with the (improper) prior that expresses total ignorance of ''p'', including ignorance with regards to the question whether the experiment can succeed, or can fail. This improper prior is 1/(''p''(1 − ''p'')) for 0 ≤ ''p'' ≤ 1 and 0 otherwise. If the calculation above is repeated with this prior, we get :P'(X_=1 \mid X_i=x_i\texti=1,\dots,n)=. Thus, with the prior specifying total ignorance, the probability of success is governed by the observed frequency of success. However, the posterior distribution that led to this result is the Beta(''s'',''n'' − ''s'') distribution, which is not proper when ''s'' = ''n'' or ''s'' = 0 (i.e. the normalisation constant is infinite when ''s'' = 0 or ''s'' = ''n''). This means that we cannot use this form of the posterior distribution to calculate the probability of the next observation succeeding when ''s'' = 0 or ''s'' = ''n''. This puts the information contained in the rule of succession in greater light: it can be thought of as expressing the prior assumption that if sampling was continued indefinitely, we would eventually observe at least one success, and at least one failure in the sample. The prior expressing total ignorance does not assume this knowledge. To evaluate the "complete ignorance" case when ''s'' = 0 or ''s'' = ''n'' can be dealt with, we first go back to the
hypergeometric distribution In probability theory and statistics, the hypergeometric distribution is a discrete probability distribution that describes the probability of k successes (random draws for which the object drawn has a specified feature) in n draws, ''without'' ...
, denoted by \mathrm(s, N,n,S). This is the approach taken in Jaynes (2003). The binomial \mathrm(r, n,p) can be derived as a limiting form, where N,S \rightarrow \infty in such a way that their ratio p= remains fixed. One can think of S as the number of successes in the total population, of size N. The equivalent prior to is , with a domain of 1\leq S \leq N-1. Working conditional to N means that estimating p is equivalent to estimating S, and then dividing this estimate by N. The posterior for S can be given as: : P(S, N,n,s) \propto \propto And it can be seen that, if ''s'' = ''n'' or ''s'' = 0, then one of the factorials in the numerator cancels exactly with one in the denominator. Taking the ''s'' = 0 case, we have: : P(S, N,n,s=0) \propto = Adding in the normalising constant, which is always finite (because there are no singularities in the range of the posterior, and there are a finite number of terms) gives: : P(S, N,n,s=0) = So the posterior expectation for p= is: : E\left(, n,s=0,N\right)=\sum_^S P(S, N,n=1,s=0)= An approximate analytical expression for large ''N'' is given by first making the approximation to the product term: : \prod_^(N-R-j)\approx (N-R)^ and then replacing the summation in the numerator with an integral : \sum_^\prod_^(N-S-j)\approx \int_1^(N-S)^ \, dS = \approx The same procedure is followed for the denominator, but the process is a bit more tricky, as the integral is harder to evaluate : \begin \sum_^ & \approx \int_1^ \, dR \\ & = N\int_1^ \, dR - \int_1^(N-R)^ \, dR \\ & = N^\left int_1^- + O\left(\right)\right\approx N^\ln(N) \end where ln is the natural logarithm plugging in these approximations into the expectation gives : E\left(, n,s=0,N\right)\approx

where the base 10
logarithm In mathematics, the logarithm is the inverse function to exponentiation. That means the logarithm of a number  to the base  is the exponent to which must be raised, to produce . For example, since , the ''logarithm base'' 10 of ...
has been used in the final answer for ease of calculation. For instance if the population is of size ''10''''k'' then probability of success on the next sample is given by: : E\left( \mid n,s=0,N=10^k \right)\approx So for example, if the population be on the order of tens of billions, so that ''k'' = 10, and we observe ''n'' = 10 results without success, then the expected proportion in the population is approximately 0.43%. If the population is smaller, so that ''n'' = 10, ''k'' = 5 (tens of thousands), the expected proportion rises to approximately 0.86%, and so on. Similarly, if the number of observations is smaller, so that ''n'' = 5, ''k'' = 10, the proportion rise to approximately 0.86% again. This probability has no positive lower bound, and can be made arbitrarily small for larger and larger choices of ''N'', or ''k''. This means that the probability depends on the size of the population from which one is sampling. In passing to the limit of infinite ''N'' (for the simpler analytic properties) we are "throwing away" a piece of very important information. Note that this ignorance relationship only holds as long as only no successes are observed. It is correspondingly revised back to the observed frequency rule p= as soon as one success is observed. The corresponding results are found for the ''s=n'' case by switching labels, and then subtracting the probability from 1.


Generalization to any number of possibilities

This section gives a heuristic derivation to that given in ''Probability Theory: The Logic of Science''. The rule of succession has many different intuitive interpretations, and depending on which intuition one uses, the generalisation may be different. Thus, the way to proceed from here is very carefully, and to re-derive the results from first principles, rather than to introduce an intuitively sensible generalisation. The full derivation can be found in Jaynes' book, but it does admit an easier to understand alternative derivation, once the solution is known. Another point to emphasise is that the prior state of knowledge described by the rule of succession is given as an enumeration of the possibilities, with the additional information that it is possible to observe each category. This can be equivalently stated as observing each category once prior to gathering the data. To denote that this is the knowledge used, an ''I''''m'' is put as part of the conditions in the probability assignments. The rule of succession comes from setting a binomial likelihood, and a uniform prior distribution. Thus a straightforward generalisation is just the multivariate extensions of these two distributions: 1) Setting a uniform prior over the initial m categories, and 2) using the
multinomial distribution In probability theory, the multinomial distribution is a generalization of the binomial distribution. For example, it models the probability of counts for each side of a ''k''-sided dice rolled ''n'' times. For ''n'' independent trials each of wh ...
as the likelihood function (which is the multivariate generalisation of the binomial distribution). It can be shown that the uniform distribution is a special case of the
Dirichlet distribution In probability and statistics, the Dirichlet distribution (after Peter Gustav Lejeune Dirichlet), often denoted \operatorname(\boldsymbol\alpha), is a family of continuous multivariate probability distributions parameterized by a vector \bold ...
with all of its parameters equal to 1 (just as the uniform is Beta(1,1) in the binary case). The Dirichlet distribution is the
conjugate prior In Bayesian probability theory, if the posterior distribution p(\theta \mid x) is in the same probability distribution family as the prior probability distribution p(\theta), the prior and posterior are then called conjugate distributions, and th ...
for the multinomial distribution, which means that the posterior distribution is also a Dirichlet distribution with different parameters. Let ''p''''i'' denote the probability that category ''i'' will be observed, and let ''n''''i'' denote the number of times category ''i'' (''i'' = 1, ..., ''m'') actually was observed. Then the joint posterior distribution of the probabilities ''p''1, ..., ''p''''m'' is given by: : f(p_1,\ldots,p_m \mid n_1,\ldots,n_m,I) = \begin , \quad & \sum_^m p_i=1 \\ \\ 0 & \text \end To get the generalised rule of succession, note that the probability of observing category ''i'' on the next observation, conditional on the ''p''''i'' is just ''p''''i'', we simply require its expectation. Letting ''A''''i'' denote the event that the next observation is in category ''i'' (''i'' = 1, ..., ''m''), and let ''n'' = ''n''1 + ... + ''n''''m'' be the total number of observations made. The result, using the properties of the Dirichlet distribution is: :P(A_i , n_1,\ldots,n_m, I_m)=. This solution reduces to the probability that would be assigned using the principle of indifference before any observations made (i.e. ''n'' = 0), consistent with the original rule of succession. It also contains the rule of succession as a special case, when ''m'' = 2, as a generalisation should. Because the propositions or events ''A''''i'' are mutually exclusive, it is possible to collapse the ''m'' categories into 2. Simply add up the ''A''''i'' probabilities that correspond to "success" to get the probability of success. Supposing that this aggregates ''c'' categories as "success" and ''m-c'' categories as "failure". Let ''s'' denote the sum of the relevant ''n''i values that have been termed "success". The probability of "success" at the next trial is then: :P(\text, n_1,\ldots,n_m, I_m)=, which is different from the original rule of succession. But note that the original rule of succession is based on ''I''2, whereas the generalisation is based on ''I''''m''. This means that the information contained in ''I''''m'' is different from that contained in ''I''2. This indicates that mere knowledge of more than two outcomes we know are possible is relevant information when collapsing these categories down to just two. This illustrates the subtlety in describing the prior information, and why it is important to specify which prior information one is using.


Further analysis

A good model is essential (i.e., a good compromise between accuracy and practicality). To paraphrase Laplace on the
sunrise problem The sunrise problem can be expressed as follows: "What is the probability that the sun will rise tomorrow?" The sunrise problem illustrates the difficulty of using probability theory when evaluating the plausibility of statements or beliefs. Acc ...
: Although we have a huge number of samples of the sun rising, there are far better models of the sun than assuming it has a certain probability of rising each day, e.g., simply having a half-life. Given a good model, it is best to make as many observations as practicable, depending on the expected reliability of prior knowledge, cost of observations, time and resources available, and accuracy required. One of the most difficult aspects of the rule of succession is not the mathematical formulas, but answering the question: When does the rule of succession apply? In the generalisation section, it was noted very explicitly by adding the prior information ''I''m into the calculations. Thus, when all that is known about a phenomenon is that there are ''m'' known possible outcomes prior to observing any data, only then does the rule of succession apply. If the rule of succession is applied in problems where this does not accurately describe the prior state of knowledge, then it may give counter-intuitive results. This is not because the rule of succession is defective, but that it is effectively answering a different question, based on different prior information. In principle (see
Cromwell's rule Cromwell's rule, named by statistician Dennis Lindley, 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 ar ...
), no possibility should have its probability (or its pseudocount) set to zero, since nothing in the physical world should be assumed strictly impossible (though it may be)—even if contrary to all observations and current theories. Indeed,
Bayes rule In probability theory and statistics, Bayes' theorem (alternatively Bayes' law or Bayes' rule), named after Thomas Bayes, describes the probability of an event, based on prior knowledge of conditions that might be related to the event. For examp ...
takes ''absolutely'' no account of an observation previously believed to have zero probability—it is still declared impossible. However, only considering a fixed set of the possibilities is an acceptable route, one just needs to remember that the results are conditional on (or restricted to) the set being considered, and not some "universal" set. In fact Larry Bretthorst shows that including the possibility of "something else" into the hypothesis space makes no difference to the relative probabilities of the other hypothesis—it simply renormalises them to add up to a value less than 1. Until "something else" is specified, the likelihood function conditional on this "something else" is indeterminate, for how is one to determine Pr(\text , \text,I) ? Thus no updating of the prior probability for "something else" can occur until it is more accurately defined. However, it is sometimes debatable whether prior knowledge should affect the relative probabilities, or also the total weight of the prior knowledge compared to actual observations. This does not have a clear cut answer, for it depends on what prior knowledge one is considering. In fact, an alternative prior state of knowledge could be of the form "I have specified ''m'' potential categories, but I am sure that only one of them is possible prior to observing the data. However, I do not know which particular category this is." A mathematical way to describe this prior is the Dirichlet distribution with all parameters equal to ''m''−1, which then gives a pseudocount of ''1'' to the denominator instead of ''m'', and adds a pseudocount of ''m''−1 to each category. This gives a slightly different probability in the binary case of \frac. Prior probabilities are only worth spending significant effort estimating when likely to have significant effect. They may be important when there are few observations — especially when so few that there have been few, if any, observations of some possibilities – such as a rare animal, in a given region. Also important when there are many observations, where it is believed that the expectation should be heavily weighted towards the prior estimates, in spite of many observations to the contrary, such as for a roulette wheel in a well-respected casino. In the latter case, at least some of the
pseudocount In statistics, additive smoothing, also called Laplace smoothing or Lidstone smoothing, is a technique used to smooth categorical data. Given a set of observation counts \textstyle from a \textstyle -dimensional multinomial distribution wit ...
s may need to be very large. They are not always small, and thereby soon outweighed by actual observations, as is often assumed. However, although a last resort, for everyday purposes, prior knowledge is usually vital. So most decisions must be subjective to some extent (dependent upon the analyst and analysis used).


See also

*
Additive smoothing In statistics, additive smoothing, also called Laplace smoothing or Lidstone smoothing, is a technique used to smooth categorical data. Given a set of observation counts \textstyle from a \textstyle -dimensional multinomial distribution with ...
* Krichevsky–Trofimov estimator *
Principle of indifference The principle of indifference (also called principle of insufficient reason) is a rule for assigning epistemic probabilities. The principle of indifference states that in the absence of any relevant evidence, agents should distribute their cre ...


References

{{DEFAULTSORT:Rule Of Succession Probability assessment Inductive reasoning