Hahn decomposition theorem

In mathematics, the Hahn decomposition theorem, named after the Austrian mathematician Hans Hahn, states that for any measurable space $(X,\Sigma )$ and any signed measure $\mu$ defined on the $\sigma$ -algebra $\Sigma$ , there exist two $\Sigma$ -measurable sets, $P$ and $N$ , of $X$ such that:

$P\cup N=X$ and $P\cap N=\varnothing$ .
For every $E\in \Sigma$ such that $E\subseteq P$ , one has $\mu (E)\geq 0$ , i.e., $P$ is a positive set for $\mu$ .
For every $E\in \Sigma$ such that $E\subseteq N$ , one has $\mu (E)\leq 0$ , i.e., $N$ is a negative set for $\mu$ .

Moreover, this decomposition is essentially unique, meaning that for any other pair $(P',N')$ of $\Sigma$ -measurable subsets of $X$ fulfilling the three conditions above, the symmetric differences $P\triangle P'$ and $N\triangle N'$ are $\mu$ -null sets in the strong sense that every $\Sigma$ -measurable subset of them has zero measure. The pair $(P,N)$ is then called a Hahn decomposition of the signed measure $\mu$ .

Jordan measure decomposition

A consequence of the Hahn decomposition theorem is the Jordan decomposition theorem, which states that every signed measure $\mu$ defined on $\Sigma$ has a unique decomposition into a difference $\mu =\mu ^{+}-\mu ^{-}$ of two positive measures, $\mu ^{+}$ and $\mu ^{-}$ , at least one of which is finite, such that ${\mu ^{+}}(E)=0$ for every $\Sigma$ -measurable subset $E\subseteq N$ and ${\mu ^{-}}(E)=0$ for every $\Sigma$ -measurable subset $E\subseteq P$ , for any Hahn decomposition $(P,N)$ of $\mu$ . We call $\mu ^{+}$ and $\mu ^{-}$ the positive and negative part of $\mu$ , respectively. The pair $(\mu ^{+},\mu ^{-})$ is called a Jordan decomposition (or sometimes Hahn–Jordan decomposition) of $\mu$ . The two measures can be defined as

{\mu ^{+}}(E):=\mu (E\cap P)\qquad {\text{and}}\qquad {\mu ^{-}}(E):=-\mu (E\cap N)

for every $E\in \Sigma$ and any Hahn decomposition $(P,N)$ of $\mu$ .

Note that the Jordan decomposition is unique, while the Hahn decomposition is only essentially unique.

The Jordan decomposition has the following corollary: Given a Jordan decomposition $(\mu ^{+},\mu ^{-})$ of a finite signed measure $\mu$ , one has

{\mu ^{+}}(E)=\sup _{B\in \Sigma ,~B\subseteq E}\mu (B)\quad {\text{and}}\quad {\mu ^{-}}(E)=-\inf _{B\in \Sigma ,~B\subseteq E}\mu (B)

for any $E$ in $\Sigma$ . Furthermore, if $\mu =\nu ^{+}-\nu ^{-}$ for a pair $(\nu ^{+},\nu ^{-})$ of finite non-negative measures on $X$ , then

\nu ^{+}\geq \mu ^{+}\quad {\text{and}}\quad \nu ^{-}\geq \mu ^{-}.

The last expression means that the Jordan decomposition is the minimal decomposition of $\mu$ into a difference of non-negative measures. This is the minimality property of the Jordan decomposition.

Proof of the Jordan decomposition: For an elementary proof of the existence, uniqueness, and minimality of the Jordan measure decomposition see Fischer (2012).

Proof of the Hahn decomposition theorem

Preparation: Assume that $\mu$ does not take the value $-\infty$ (otherwise decompose according to $-\mu$ ). As mentioned above, a negative set is a set $A\in \Sigma$ such that $\mu (B)\leq 0$ for every $\Sigma$ -measurable subset $B\subseteq A$ .

Claim: Suppose that $D\in \Sigma$ satisfies $\mu (D)\leq 0$ . Then there is a negative set $A\subseteq D$ such that $\mu (A)\leq \mu (D)$ .

Proof of the claim: Define $A_{0}:=D$ . Inductively assume for $n\in \mathbb {N} _{0}$ that $A_{n}\subseteq D$ has been constructed. Let

t_{n}:=\sup(\{\mu (B)\mid B\in \Sigma ~{\text{and}}~B\subseteq A_{n}\})

denote the supremum of $\mu (B)$ over all the $\Sigma$ -measurable subsets $B$ of $A_{n}$ . This supremum might a priori be infinite. As the empty set $\varnothing$ is a possible candidate for $B$ in the definition of $t_{n}$ , and as $\mu (\varnothing )=0$ , we have $t_{n}\geq 0$ . By the definition of $t_{n}$ , there then exists a $\Sigma$ -measurable subset $B_{n}\subseteq A_{n}$ satisfying

\mu (B_{n})\geq \min \!\left(1,{\frac {t_{n}}{2}}\right).

Set $A_{n+1}:=A_{n}\setminus B_{n}$ to finish the induction step. Finally, define

A:=D{\Bigg \backslash }\bigcup _{n=0}^{\infty }B_{n}.

As the sets $(B_{n})_{n=0}^{\infty }$ are disjoint subsets of $D$ , it follows from the sigma additivity of the signed measure $\mu$ that

\mu (D)=\mu (A)+\sum _{n=0}^{\infty }\mu (B_{n})\geq \mu (A)+\sum _{n=0}^{\infty }\min \!\left(1,{\frac {t_{n}}{2}}\right)\geq \mu (A).

This shows that $\mu (A)\leq \mu (D)$ . Assume $A$ were not a negative set. This means that there would exist a $\Sigma$ -measurable subset $B\subseteq A$ that satisfies $\mu (B)>0$ . Then $t_{n}\geq \mu (B)$ for every $n\in \mathbb {N} _{0}$ , so the series on the right would have to diverge to $+\infty$ , implying that $\mu (D)=+\infty$ , which is a contradiction, since $\mu (D)\leq 0$ . Therefore, $A$ must be a negative set.

Construction of the decomposition: Set $N_{0}=\varnothing$ . Inductively, given $N_{n}$ , define

s_{n}:=\inf(\{\mu (D)\mid D\in \Sigma ~{\text{and}}~D\subseteq X\setminus N_{n}\}).

as the infimum of $\mu (D)$ over all the $\Sigma$ -measurable subsets $D$ of $X\setminus N_{n}$ . This infimum might a priori be $-\infty$ . As $\varnothing$ is a possible candidate for $D$ in the definition of $s_{n}$ , and as $\mu (\varnothing )=0$ , we have $s_{n}\leq 0$ . Hence, there exists a $\Sigma$ -measurable subset $D_{n}\subseteq X\setminus N_{n}$ such that

\mu (D_{n})\leq \max \!\left({\frac {s_{n}}{2}},-1\right)\leq 0.

By the claim above, there is a negative set $A_{n}\subseteq D_{n}$ such that $\mu (A_{n})\leq \mu (D_{n})$ . Set $N_{n+1}:=N_{n}\cup A_{n}$ to finish the induction step. Finally, define

N:=\bigcup _{n=0}^{\infty }A_{n}.

As the sets $(A_{n})_{n=0}^{\infty }$ are disjoint, we have for every $\Sigma$ -measurable subset $B\subseteq N$ that

\mu (B)=\sum _{n=0}^{\infty }\mu (B\cap A_{n})

by the sigma additivity of $\mu$ . In particular, this shows that $N$ is a negative set. Next, define $P:=X\setminus N$ . If $P$ were not a positive set, there would exist a $\Sigma$ -measurable subset $D\subseteq P$ with $\mu (D)<0$ . Then $s_{n}\leq \mu (D)$ for all $n\in \mathbb {N} _{0}$ and

\mu (N)=\sum _{n=0}^{\infty }\mu (A_{n})\leq \sum _{n=0}^{\infty }\max \!\left({\frac {s_{n}}{2}},-1\right)=-\infty ,

which is not allowed for $\mu$ . Therefore, $P$ is a positive set.

Proof of the uniqueness statement: Suppose that $(N',P')$ is another Hahn decomposition of $X$ . Then $P\cap N'$ is a positive set and also a negative set. Therefore, every measurable subset of it has measure zero. The same applies to $N\cap P'$ . As

P\triangle P'=N\triangle N'=(P\cap N')\cup (N\cap P'),

this completes the proof. Q.E.D.

References

Billingsley, Patrick (1995). Probability and Measure -- Third Edition. Wiley Series in Probability and Mathematical Statistics. New York: John Wiley & Sons. ISBN 0-471-00710-2.
Fischer, Tom (2012). "Existence, uniqueness, and minimality of the Jordan measure decomposition". arXiv:1206.5449 [math.ST].

External links

Hahn decomposition theorem at PlanetMath.
"Hahn decomposition", Encyclopedia of Mathematics, EMS Press, 2001 [1994]
"Jordan decomposition (of a signed measure)", Encyclopedia of Mathematics, EMS Press, 2001 [1994]