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A '''probability''' is a number representing how likely a random event or an uncertain proposition is, ranging from 1 representing certainty down to 0 for impossibility.
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A '''probability''' is a number representing the likelihood of a random event or an uncertain proposition occurring, ranging from 1 representing certainty down to 0 for impossibility.


Probability is the topic of [[probability theory]], a branch of [[mathematics]] concerned with analysis of random phenomena.  Like algebra, geometry and other parts of mathematics,  probability theory has its origins in the natural world. Humans routinely deal with incomplete and/or uncertain information in daily life: in decisions such as crossing the road ("will this approaching car respect the red light?"), eating food ("am I certain this food is not contaminated?"), and so on.  Probability theory is a mathematical tool intended to formalize this ubiquitous mental process. The probability concept is a part of this theory, and is intended to formalize uncertainty.
Probability is the topic of [[probability theory]], a branch of [[mathematics]] concerned with analysis of random phenomena.  Like algebra, geometry and other parts of mathematics,  probability theory has its origins in the natural world. Humans routinely deal with incomplete and/or uncertain information in daily life: in decisions such as crossing the road ("Will this approaching car respect the red light?"), eating food ("Am I certain this food is not contaminated?"), and so on.  Probability theory is a mathematical tool intended to formalize this ubiquitous mental process. The probability concept is a part of this theory, and is intended to formalize uncertainty.


There are three basic ways to think about the probability concept:
There are three basic ways to think about the probability concept:
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* Bayesian probability.
* Bayesian probability.
* Frequentist  probability.
* Frequentist  probability.
* Axiomatic probability (Kolmogorov's axioms).
* Axiomatic probability.


== Bayesian probability ==
== Bayesian probability ==
In this approach, probability is taken as a measure of how reasonable a belief is in light of experience or observations. It is based on a rigorous relationship between what are called [[conditional probability|conditional probabilities]] and ordinary (non-conditional) probability. It is thus, not simply an intuitive or educated "guess", but something much more specific and precise.
{{main|Bayes Theorem|Statistical significance}}
According to [[Bayes Theorem]], probability is taken as a measure of how reasonable a belief is in light of prior observations and theoretical considerations.


=== Example of the Bayesian viewpoint ===
=== Example of the Bayesian viewpoint ===
How likely is it that it will rain today? If I'm inside a room with no windows and cannot look outside and see whether there are any clouds in the sky or wshether the wind is blowing, then I do not have this information available, and cannot use it to inform my estimate of how likely it is that it going to rain. But of the last 100 cloudy days I've experienced, I've noticed that it rained on 20 of them, and that of days without a cloud in the sky it has only rained on five (because a storm blew in later in the day), I will conclude that rain is more likely on cloudy days. In fact, this can be made precise using a formula known as [[Bayes' theorem]] which expresses the probability of rain ''given'' that it is cloudy in terms of the probability that it will rain on a cloudy day (something I can estimate by direct observation), the probability that it will rain on a given day, and the probability that it will be cloudy on a given day (both of which I can estimate by direct observation).
 
A Bayesian may assign a probability of 1/2 to the proposition that there was life on [[Mars]] a billion years ago.  A frequentist would not do that, since one cannot say that the event that there was life on Mars a billion years ago happens in half of all cases; there are no such cases.


== Frequentist probability ==
== Frequentist probability ==
In this approach one views probabilities as the proportion of identical (or as nearly identical as we can manage) experiments will have a given outcome.
In this approach one views probabilities as reflecting the frequencies of the various outcomes,  if an infinite number of tests is carried out.
 


=== Example of the frequentist viewpoint ===
=== Example of the frequentist viewpoint ===
The classic example here is flipping a coin. If out of 1000 coin flips, 501 are "heads" and 499 are "tails", a frequentist will say that (based on this experiment) the probability of heads is .501. Now, if the outcome is trculy random, then if we flip the coin 10,000 times (or 100,000 times), the proportion of heads will come even closer to .5. The .501 we derived by flipping our coin 1000 times is only an estimate of the true probability. The difficulty is that we can only carry out experiments a finite number of times, so the frequentist approach doesn't tell us exactly what the probability should be, either.
The probability of "heads" when flipping a fair coin is 50%, because when we flip it an infinite number of times, that's what the frequency will be.
 


==The axiomatic approach==
==The axiomatic approach==


Neither the Bayesian or the frequentist approach really tells us how to compute probabilities (though we can ''estimate'' them). But just as importantly, they don't really give us a satisfactory explanation of what probability is. The axiomattic approach takes a different tack. Instead of focusing on the question "What is probability?" we step back and ask "How does probability ''work''?" The set of rules we expect probability to follow is known as Kolmogorov's axioms. But the ultimate justification for this approach rests on experience, too. If Kolmogorov's axioms le us to conclude that coins never came up tails, then we would naturally conclude that something is wrong. Fortunately, the results e derive by applying these axioms accord very nicely with experience. We can even derive Bayes' theorem as a consequence, and we can show that in a large number of trials of n experiment, the frequency of one outcome (often called "success") will give us a good estimate of the probability, and that estimte will become better and better as the number of trials increases &em; or at least it will do so ''on the average''.
Neither the Bayesian nor the frequentist approach really give us a satisfactory [[formal structure]] for development of a rigid theory.  
 
The axiomatic approach takes a different tack. Instead of focusing on the question "What is probability?" we step back and ask "How does probability ''work''?"  
 
We then focus on abstract mathematical concepts such as [[set|sets]], [[measure (mathematics)|measure]], [[sigma algebra|sigma algebras]] and a set of rules we expect probability to followknown as [[Kolmogorov's axioms]].  
 
But the ultimate justification for this approach rests on experience, too. Fortunately, the results derived by applying these axioms accord very nicely with experience. We can also derive Bayes' theorem as a consequence, and we can show that in a large number of trials, the frequencies will give us a good estimate of the probabilities; or at least it will do so ''on average''.


===Example of the axiomatic approach===
===Example of the axiomatic approach===
Given a standard deck of card.  We want to draw a card at random.


If the probability that a card (drawn at random from a standard deck of cards) is a heart is .25, and the probability that it is a spade is also .25, and if I know that the being a heart and being a spade are mutually exclusive possibilities (i.e., a card cannot be both), then the probability that it is a heart ''or'' a spade is .5 = 0.25 + 0.25.
This experiment can be modeled by a set of 52 possible outcomes.  Any set with 52 elements has exactly <math>2^{52}</math> subsets.  To each of those subsets we may assign a certain number (a "probability"),  so that certain axioms are satisfied.  We choose to assign probability .25 to the subset consisting of all 13 hearts.  We also assign .25 the the subset consisting of all spades.
 
According to the axioms,  we must then assign probability 0.5 to the subset consisting of every spade and heart in the deck.
 
In non-axiomatic informal terms,  we would describe this result thus:
 
If the probability that a card (drawn at random from a standard deck of cards) is a heart is .25, and the probability that it is a spade is also .25, and if I know that the being a heart and being a spade are mutually exclusive possibilities (i.e., a card cannot be both), then the probability that it is a heart ''or'' a spade is 0.5 = 0.25 + 0.25.


== More technical information ==
== More technical information ==
* [[Bayes' theorem]]
* [[Bayes Theorem]]
* [[principle of maximum entropy]]
* [[principle of maximum entropy]]
* [[Probability distributions]]
* [[Probability distributions]]
* [[Kolmogorov's axioms]]
* [[Kolmogorov's axioms]]
* [[probability theory]]
* [[probability theory]]
* [[probability space]]


== See also ==
== See also ==
* [[statistics]]
* [[Statistics]]
* [[subjective probability]]
* [[Statistical significance]]
* [[objective probability]]


== External links ==
== External links ==
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*More advanced
*More advanced
** http://bayes.wustl.edu/
** http://bayes.wustl.edu/
** http://plato.stanford.edu/entries/probability-interpret/
** http://plato.stanford.edu/entries/probability-interpret/[[Category:Suggestion Bot Tag]]
 
[[Category:CZ Live]]
[[Category:Mathematics Workgroup]]

Latest revision as of 11:00, 7 October 2024

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A probability is a number representing the likelihood of a random event or an uncertain proposition occurring, ranging from 1 representing certainty down to 0 for impossibility.

Probability is the topic of probability theory, a branch of mathematics concerned with analysis of random phenomena. Like algebra, geometry and other parts of mathematics, probability theory has its origins in the natural world. Humans routinely deal with incomplete and/or uncertain information in daily life: in decisions such as crossing the road ("Will this approaching car respect the red light?"), eating food ("Am I certain this food is not contaminated?"), and so on. Probability theory is a mathematical tool intended to formalize this ubiquitous mental process. The probability concept is a part of this theory, and is intended to formalize uncertainty.

There are three basic ways to think about the probability concept:

  • Bayesian probability.
  • Frequentist probability.
  • Axiomatic probability.

Bayesian probability

For more information, see: Bayes Theorem and Statistical significance.

According to Bayes Theorem, probability is taken as a measure of how reasonable a belief is in light of prior observations and theoretical considerations.

Example of the Bayesian viewpoint

A Bayesian may assign a probability of 1/2 to the proposition that there was life on Mars a billion years ago. A frequentist would not do that, since one cannot say that the event that there was life on Mars a billion years ago happens in half of all cases; there are no such cases.

Frequentist probability

In this approach one views probabilities as reflecting the frequencies of the various outcomes, if an infinite number of tests is carried out.


Example of the frequentist viewpoint

The probability of "heads" when flipping a fair coin is 50%, because when we flip it an infinite number of times, that's what the frequency will be.


The axiomatic approach

Neither the Bayesian nor the frequentist approach really give us a satisfactory formal structure for development of a rigid theory.

The axiomatic approach takes a different tack. Instead of focusing on the question "What is probability?" we step back and ask "How does probability work?"

We then focus on abstract mathematical concepts such as sets, measure, sigma algebras and a set of rules we expect probability to follow, known as Kolmogorov's axioms.

But the ultimate justification for this approach rests on experience, too. Fortunately, the results derived by applying these axioms accord very nicely with experience. We can also derive Bayes' theorem as a consequence, and we can show that in a large number of trials, the frequencies will give us a good estimate of the probabilities; or at least it will do so on average.

Example of the axiomatic approach

Given a standard deck of card. We want to draw a card at random.

This experiment can be modeled by a set of 52 possible outcomes. Any set with 52 elements has exactly subsets. To each of those subsets we may assign a certain number (a "probability"), so that certain axioms are satisfied. We choose to assign probability .25 to the subset consisting of all 13 hearts. We also assign .25 the the subset consisting of all spades.

According to the axioms, we must then assign probability 0.5 to the subset consisting of every spade and heart in the deck.

In non-axiomatic informal terms, we would describe this result thus:

If the probability that a card (drawn at random from a standard deck of cards) is a heart is .25, and the probability that it is a spade is also .25, and if I know that the being a heart and being a spade are mutually exclusive possibilities (i.e., a card cannot be both), then the probability that it is a heart or a spade is 0.5 = 0.25 + 0.25.

More technical information

See also

External links