Probability measure: Difference between revisions

Latest revision as of 23:48, 21 September 2025

Template:Short description Template:Use American English Template:Probability fundamentals In mathematics, a probability measure is a real-valued function defined on a set of events in a σ-algebra that satisfies measure properties such as countable additivity.^[1] The difference between a probability measure and the more general notion of measure (which includes concepts like area or volume) is that a probability measure must assign value 1 to the entire space.

Intuitively, the additivity property says that the probability assigned to the union of two disjoint (mutually exclusive) events by the measure should be the sum of the probabilities of the events; for example, the value assigned to the outcome "1 or 2" in a throw of a die should be the sum of the values assigned to the outcomes "1" and "2".

Probability measures have applications in diverse fields, from physics to finance and biology.

Definition

File:Probability-measure.svg

A probability measure mapping the σ-algebra for

2^{3}

events to the unit interval.

The requirements for a set function $μ$ to be a probability measure on a σ-algebra are that:

$μ$ must take values in the unit interval $[0, 1],$ including $0$ on the empty set and $1$ on the entire space.
$μ$ must satisfy the countable additivity property that for all countable collections $E_{1}, E_{2}, \dots$ of pairwise disjoint sets: $μ (⋃_{i \in ℕ} E_{i}) = \sum_{i \in ℕ} μ (E_{i}) .$

For example, given three elements 1, 2 and 3 with probabilities $1 / 4, 1 / 4$ and $1 / 2,$ the value assigned to ${1, 3}$ is $1 / 4 + 1 / 2 = 3 / 4,$ as in the diagram on the right.

The conditional probability based on the intersection of events defined as: $μ (B ∣ A) = \frac{μ (A \cap B)}{μ (A)} .$ satisfies the probability function requirements so long as $μ (A)$ is not zero.^[2]^[3]

Probability measures are distinct from the more general notion of fuzzy measures in which there is no requirement that the fuzzy values sum up to $1,$ and the additive property is replaced by an order relation based on set inclusion.

Example applications

In many cases, statistical physics uses probability measures, but not all measures it uses are probability measures.Template:Clarify^[4]^[5]

Market measures which assign probabilities to financial market spaces based on observed market movements are examples of probability measures which are of interest in mathematical finance; for example, in the pricing of financial derivatives.^[6] For instance, a risk-neutral measure is a probability measure which assumes that the current value of assets is the expected value of the future payoff taken with respect to that same risk neutral measure (i.e. calculated using the corresponding risk neutral density function), and discounted at the risk-free rate. If there is a unique probability measure that must be used to price assets in a market, then the market is called a complete market.^[7]

Not all measures that intuitively represent chance or likelihood are probability measures. For instance, although the fundamental concept of a system in statistical mechanics is a measure space, such measures are not always probability measures.^[4] In statistical physics, for sentences of the form "the probability of a system S assuming state A is p," the geometry of the system does not always lead to the definition of a probability measure under congruence, although it may do so in the case of systems with just one degree of freedom.^[5]

Probability measures are also used in mathematical biology.^[8] For instance, in comparative sequence analysis a probability measure may be defined for the likelihood that a variant may be permissible for an amino acid in a sequence.^[9]

References

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External links

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pl:Miara probabilistyczna

↑ An introduction to measure-theoretic probability by George G. Roussas 2004 Template:Isbn page 47
↑ Script error: No such module "Citation/CS1".
↑ Probability, Random Processes, and Ergodic Properties by Robert M. Gray 2009 Template:Isbn page 163
↑ ^a ^b A course in mathematics for students of physics, Volume 2 by Paul Bamberg, Shlomo Sternberg 1991 Template:Isbn page 802
↑ ^a ^b The concept of probability in statistical physics by Yair M. Guttmann 1999 Template:Isbn page 149
↑ Quantitative methods in derivatives pricing by Domingo Tavella 2002 Template:Isbn page 11
↑ Irreversible decisions under uncertainty by Svetlana I. Boyarchenko, Serge Levendorskiĭ 2007 Template:Isbn page 11
↑ Mathematical Methods in Biology by J. David Logan, William R. Wolesensky 2009 Template:Isbn page 195
↑ Discovering biomolecular mechanisms with computational biology by Frank Eisenhaber 2006 Template:Isbn page 127

[1] An introduction to measure-theoretic probability by George G. Roussas 2004 Template:Isbn page 47

[2] Script error: No such module "Citation/CS1".

[3] Probability, Random Processes, and Ergodic Properties by Robert M. Gray 2009 Template:Isbn page 163

[stern-4] A course in mathematics for students of physics, Volume 2 by Paul Bamberg, Shlomo Sternberg 1991 Template:Isbn page 802

[gut-5] The concept of probability in statistical physics by Yair M. Guttmann 1999 Template:Isbn page 149

[6] Quantitative methods in derivatives pricing by Domingo Tavella 2002 Template:Isbn page 11

[7] Irreversible decisions under uncertainty by Svetlana I. Boyarchenko, Serge Levendorskiĭ 2007 Template:Isbn page 11

[8] Mathematical Methods in Biology by J. David Logan, William R. Wolesensky 2009 Template:Isbn page 195

[9] Discovering biomolecular mechanisms with computational biology by Frank Eisenhaber 2006 Template:Isbn page 127

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@@ Line 4: / Line 4: @@
 In [[mathematics]], a '''probability measure''' is a [[real-valued function]] defined on a set of events in a [[σ-algebra]] that satisfies [[Measure (mathematics)|measure]] properties such as ''countable additivity''.<ref>''An introduction to measure-theoretic probability'' by George G. Roussas 2004 {{isbn|0-12-599022-7}} [https://books.google.com/books?id=J8ZRgCNS-wcC&pg=PA47 page 47]</ref>  The difference between a probability measure and the more general notion of measure (which includes concepts like [[area]] or [[volume]]) is that a probability measure must assign value 1 to the entire space.
-Intuitively, the additivity property says that the probability assigned to the union of two disjoint (mutually exclusive) events by the measure should be the sum of the probabilities of the events; for example, the value assigned to the outcome "1 or 2" in a throw of a dice should be the sum of the values assigned to the outcomes "1" and "2".
+Intuitively, the additivity property says that the probability assigned to the union of two disjoint (mutually exclusive) events by the measure should be the sum of the probabilities of the events; for example, the value assigned to the outcome "1 or 2" in a throw of a die should be the sum of the values assigned to the outcomes "1" and "2".
 Probability measures have applications in diverse fields, from physics to finance and biology.
@@ Line 12: / Line 12: @@
 The requirements for a [[set function]] <math>\mu</math> to be a probability measure on a [[σ-algebra]] are that:
-* <math>\mu</math> must return results in the [[unit interval]] <math>[0, 1],</math> returning <math>0</math> for the empty set and <math>1</math> for the entire space.
+* <math>\mu</math> must take values in the [[unit interval]] <math>[0, 1],</math> including <math>0</math> on the empty set and <math>1</math> on the entire space.
 * <math>\mu</math> must satisfy the ''[[Sigma-additive set function|countable additivity]]'' property that for all [[countable]] collections <math>E_1, E_2, \ldots</math> of pairwise [[disjoint sets]]: <math display=block> \mu\left(\bigcup_{i \in \N} E_i\right) = \sum_{i \in \N} \mu(E_i).</math>
@@ Line 32: / Line 32: @@
 Probability measures are also used in [[mathematical biology]].<ref>''Mathematical Methods in Biology'' by J. David Logan, William R. Wolesensky 2009 {{isbn|0-470-52587-8}} [https://books.google.com/books?id=6GGyquH8kLcC&pg=PA195 page 195]</ref> For instance, in comparative [[sequence analysis]] a probability measure may be defined for the likelihood that a variant may be permissible for an [[amino acid]] in a sequence.<ref>''Discovering biomolecular mechanisms with computational biology'' by Frank Eisenhaber 2006 {{isbn|0-387-34527-2}} [https://books.google.com/books?id=Pygg7cIZTwIC&pg=PA127 page 127]</ref>
-[[Ultrafilter]]s can be understood as <math>\{0, 1\}</math>-valued probability measures, allowing for many intuitive proofs based upon measures. For instance, [[Hindman’s theorem|Hindman's Theorem]] can be proven from the further investigation of these measures, and their [[convolution]] in particular.
 ==See also==

Probability measure: Difference between revisions

Latest revision as of 23:48, 21 September 2025

Contents

Definition

Example applications

See also

References

Further reading

External links

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Probability measure: Difference between revisions

Latest revision as of 23:48, 21 September 2025

Definition

Example applications

See also

References

Further reading

External links

Navigation menu

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