Statement:
Let be a Sigma-Finite Measure space and be another -finite measure on the same measurable space such that (i.e., is absolutely continuous with respect to ). Then there exists a measurable function , called the Radon-Nikodym derivative, such that:

The function is denoted by and satisfies:

Intuition:
The Radon-Nikodym theorem allows us to express the measure as being “scaled” by a density function with respect to the reference measure . This is analogous to expressing one probability distribution in terms of another via a probability density function.

Key Properties:

  • The Radon-Nikodym derivative is unique -almost everywhere.
  • If is a probability measure, can be interpreted as the conditional density of relative to .

Proof Outline:

  1. Construct a sequence of sets with that cover .
  2. Apply the Hahn Decomposition Theorem to decompose into positive and negative parts, where is chosen iteratively.
  3. Prove that this construction results in a valid Radon-Nikodym derivative using monotone convergence arguments.