The Hahn Decomposition Theorem is a result in measure theory that applies to signed measures. It states that any measurable space can be divided into two disjoint sets: one on which a signed measure is non-negative and one on which it is non-positive.

Statement

Let be a measurable space, and let be a signed measure on . Then, there exist two disjoint measurable sets such that:

  1. (the sets and form a partition of ),
  2. for every measurable subset ,
  3. for every measurable subset .

The sets and are called a Hahn decomposition of with respect to the signed measure . This decomposition is not unique, but any two Hahn decompositions will differ only by a set of measure zero.

Key Implications

  1. Jordan Decomposition
  2. Total Variation

Outline of Proof

  1. Supremum of Positive Sets: Define as the set where is “maximally positive” by considering subsets with non-negative measure and taking a supremum.
  2. Complement as Negative Set: Define . By construction, will be the set where is “maximally negative.”
  3. Verification: Show that is non-negative on all subsets of and non-positive on all subsets of , completing the decomposition.

The Hahn Decomposition Theorem is foundational for further analysis in measure theory, particularly in the study of signed and complex measures.