A π-system is a non-empty collection of sets ${\displaystyle P}$  that is closed under non-empty finite intersections, which is equivalent to ${\displaystyle P}$  containing the intersection of any two of its elements. If every set in this π-system is a subset of ${\displaystyle \Omega }$  then it is called a π-system on ${\displaystyle \Omega .}$ 

For any non-empty family ${\displaystyle \Sigma }$  of subsets of ${\displaystyle \Omega ,}$  there exists a π-system ${\displaystyle {\mathcal {I}}_{\Sigma },}$  called the π-system generated by ${\displaystyle {\boldsymbol {\varSigma }}}$ , that is the unique smallest π-system of ${\displaystyle \Omega }$  containing every element of ${\displaystyle \Sigma .}$  It is equal to the intersection of all π-systems containing ${\displaystyle \Sigma ,}$  and can be explicitly described as the set of all possible non-empty finite intersections of elements of ${\displaystyle \Sigma :}$ 

A non-empty family of sets has the finite intersection property if and only if the π-system it generates does not contain the empty set as an element.

• For any real numbers ${\displaystyle a}$  and ${\displaystyle b,}$  the intervals ${\displaystyle (-\infty ,a]}$  form a π-system, and the intervals ${\displaystyle (a,b]}$  form a π-system if the empty set is also included.
• The topology (collection of open subsets) of any topological space is a π-system.
• Every filter is a π-system. Every π-system that doesn't contain the empty set is a prefilter (also known as a filter base).
• For any measurable function ${\displaystyle f:\Omega \to \mathbb {R} ,}$  the set  ${\displaystyle {\mathcal {I}}_{f}=\left\{f^{-1}((-\infty ,x]):x\in \mathbb {R} \right\}}$  defines a π-system, and is called the π-system generated by ${\displaystyle f.}$  (Alternatively, ${\displaystyle \left\{f^{-1}((a,b]):a,b\in \mathbb {R} ,a<b\right\}\cup \{\varnothing \}}$  defines a π-system generated by ${\displaystyle f.}$ )
• If ${\displaystyle P_{1}}$  and ${\displaystyle P_{2}}$  are π-systems for ${\displaystyle \Omega _{1}}$  and ${\displaystyle \Omega _{2},}$  respectively, then ${\displaystyle \{A_{1}\times A_{2}:A_{1}\in P_{1},A_{2}\in P_{2}\}}$  is a π-system for the Cartesian product ${\displaystyle \Omega _{1}\times \Omega _{2}.}$ 
• Every 𝜎-algebra is a π-system.

A 𝜆-system on ${\displaystyle \Omega }$  is a set ${\displaystyle D}$  of subsets of ${\displaystyle \Omega ,}$  satisfying

• ${\displaystyle \Omega \in D,}$ 
• if ${\displaystyle A\in D}$  then ${\displaystyle \Omega \setminus A\in D,}$ 
• if ${\displaystyle A_{1},A_{2},A_{3},\ldots }$  is a sequence of (pairwise) disjoint subsets in ${\displaystyle D}$  then ${\displaystyle \textstyle \bigcup \limits _{n=1}^{\infty }A_{n}\in D.}$ 

Whilst it is true that any 𝜎-algebra satisfies the properties of being both a π-system and a 𝜆-system, it is not true that any π-system is a 𝜆-system, and moreover it is not true that any π-system is a 𝜎-algebra. However, a useful classification is that any set system which is both a 𝜆-system and a π-system is a 𝜎-algebra. This is used as a step in proving the π-𝜆 theorem.

The π-𝜆 theorem

Let ${\displaystyle D}$  be a 𝜆-system, and let  ${\displaystyle {\mathcal {I}}\subseteq D}$  be a π-system contained in ${\displaystyle D.}$  The π-𝜆 theorem^[1] states that the 𝜎-algebra ${\displaystyle \sigma ({\mathcal {I}})}$  generated by ${\displaystyle {\mathcal {I}}}$  is contained in ${\displaystyle D~:~}$  ${\displaystyle \sigma ({\mathcal {I}})\subseteq D.}$ 

The π-𝜆 theorem can be used to prove many elementary measure theoretic results. For instance, it is used in proving the uniqueness claim of the Carathéodory extension theorem for 𝜎-finite measures.^[2]

The π-𝜆 theorem is closely related to the monotone class theorem, which provides a similar relationship between monotone classes and algebras, and can be used to derive many of the same results. Since π-systems are simpler classes than algebras, it can be easier to identify the sets that are in them while, on the other hand, checking whether the property under consideration determines a 𝜆-system is often relatively easy. Despite the difference between the two theorems, the π-𝜆 theorem is sometimes referred to as the monotone class theorem.^[1]

Example

Let ${\displaystyle \mu _{1},\mu _{2}:F\to \mathbb {R} }$  be two measures on the 𝜎-algebra ${\displaystyle F,}$  and suppose that ${\displaystyle F=\sigma (I)}$  is generated by a π-system ${\displaystyle I.}$  If

1. ${\displaystyle \mu _{1}(A)=\mu _{2}(A)}$  for all ${\displaystyle A\in I,}$  and
2. ${\displaystyle \mu _{1}(\Omega )=\mu _{2}(\Omega )<\infty ,}$ 

then ${\displaystyle \mu _{1}=\mu _{2}.}$  This is the uniqueness statement of the Carathéodory extension theorem for finite measures. If this result does not seem very remarkable, consider the fact that it usually is very difficult or even impossible to fully describe every set in the 𝜎-algebra, and so the problem of equating measures would be completely hopeless without such a tool.

Idea of the proof^[2] Define the collection of sets

π-systems are more commonly used in the study of probability theory than in the general field of measure theory. This is primarily due to probabilistic notions such as independence, though it may also be a consequence of the fact that the π-𝜆 theorem was proven by the probabilist Eugene Dynkin. Standard measure theory texts typically prove the same results via monotone classes, rather than π-systems.

Equality in distribution

The π-𝜆 theorem motivates the common definition of the probability distribution of a random variable ${\displaystyle X:(\Omega ,{\mathcal {F}},\operatorname {P} )\to \mathbb {R} }$  in terms of its cumulative distribution function. Recall that the cumulative distribution of a random variable is defined as

A similar result holds for the joint distribution of a random vector. For example, suppose ${\displaystyle X}$  and ${\displaystyle Y}$  are two random variables defined on the same probability space ${\displaystyle (\Omega ,{\mathcal {F}},\operatorname {P} ),}$  with respectively generated π-systems ${\displaystyle {\mathcal {I}}_{X}}$  and ${\displaystyle {\mathcal {I}}_{Y}.}$  The joint cumulative distribution function of ${\displaystyle (X,Y)}$  is

However, ${\displaystyle A=X^{-1}((-\infty ,a])\in {\mathcal {I}}_{X}}$  and ${\displaystyle B=Y^{-1}((-\infty ,b])\in {\mathcal {I}}_{Y}.}$  Because

In the theory of stochastic processes, two processes ${\displaystyle (X_{t})_{t\in T},(Y_{t})_{t\in T}}$  are known to be equal in distribution if and only if they agree on all finite-dimensional distributions; that is, for all ${\displaystyle t_{1},\ldots ,t_{n}\in T,\,n\in \mathbb {N} ,}$ 

The proof of this is another application of the π-𝜆 theorem.^[3]

Independent random variables

The theory of π-system plays an important role in the probabilistic notion of independence. If ${\displaystyle X}$  and ${\displaystyle Y}$  are two random variables defined on the same probability space ${\displaystyle (\Omega ,{\mathcal {F}},\operatorname {P} )}$  then the random variables are independent if and only if their π-systems ${\displaystyle {\mathcal {I}}_{X},{\mathcal {I}}_{Y}}$  satisfy for all ${\displaystyle A\in {\mathcal {I}}_{X}}$  and ${\displaystyle B\in {\mathcal {I}}_{Y},}$ 

Example

Let ${\displaystyle Z=\left(Z_{1},Z_{2}\right),}$  where ${\displaystyle Z_{1},Z_{2}\sim {\mathcal {N}}(0,1)}$  are iid standard normal random variables. Define the radius and argument (arctan) variables

Then ${\displaystyle R}$  and ${\displaystyle \Theta }$  are independent random variables.

To prove this, it is sufficient to show that the π-systems ${\displaystyle {\mathcal {I}}_{R},{\mathcal {I}}_{\Theta }}$  are independent: that is, for all ${\displaystyle \rho \in [0,\infty )}$  and ${\displaystyle \theta \in [0,2\pi ],}$ 

Confirming that this is the case is an exercise in changing variables. Fix ${\displaystyle \rho \in [0,\infty )}$  and ${\displaystyle \theta \in [0,2\pi ],}$  then the probability can be expressed as an integral of the probability density function of ${\displaystyle Z.}$ 

• δ-ring – Ring closed under countable intersections
• Field of sets – Algebraic concept in measure theory, also referred to as an algebra of sets
• Ideal (set theory) – Non-empty family of sets that is closed under finite unions and subsets
• Independence (probability theory) – Fundamental concept in probability theory
• 𝜆-system (Dynkin system) – Family closed under complements and countable disjoint unions
• Monotone class theorem
• Probability distribution – Mathematical function for the probability a given outcome occurs in an experiment
• Ring of sets – Family closed under unions and relative complements
• σ-algebra – Algebric structure of set algebra
• 𝜎-ideal – Family closed under subsets and countable unions
• 𝜎-ring – Ring closed under countable unions

• Gut, Allan (2005). Probability: A Graduate Course. Springer Texts in Statistics. New York: Springer. doi:10.1007/b138932. ISBN 0-387-22833-0.
• Williams, David (1991). Probability with Martingales. Cambridge University Press. ISBN 0-521-40605-6.
• Durrett, Richard (2019). Probability: Theory and Examples (PDF). Cambridge Series in Statistical and Probabilistic Mathematics. Vol. 49 (5th ed.). Cambridge New York, NY: Cambridge University Press. ISBN 978-1-108-47368-2. OCLC 1100115281. Retrieved November 5, 2020.