Integral of Integrable Function is Additive/Corollary 1

Corollary
Let $\struct {X, \Sigma, \mu}$ be a measure space. Let $f, g: X \to \overline \R$ be $\mu$-integrable functions.

Suppose that the pointwise sum $f + g$ is well-defined.

Then $f + g$ is $\mu$-integrable, with:


 * $\displaystyle \int \paren {f + g} \rd \mu = \int f \rd \mu + \int g \rd \mu$

Proof
Define:


 * $A = \set {x \in X : \map f x \in \R}$

and:


 * $B = \set {x \in X : \map g x \in \R}$

From Set of Points for which Measurable Function is Real-Valued is Measurable, we have that:


 * $A$ and $B$ are $\Sigma$-measurable.

From $\sigma$-Algebra Closed under Countable Intersection, we have that:


 * $A \cap B$ is $\Sigma$-measurable.

From Integral of Integrable Function over Measurable Set is Well-Defined, we have that:


 * $f \cdot \chi_{A \cap B}$ and $g \cdot \chi_{A \cap B}$ are $\mu$-integrable.

Since whenever $x \in X$ is such that $\size {\map f x} = +\infty$ or $\size {\map g x} = +\infty$, we have $\map {\chi_{A \cap B} } x = 0$, these are both functions $X \to \R$.

So, we can apply Integral of Integrable Function is Additive to obtain:


 * $f \cdot \chi_{A \cap B} + g \cdot \chi_{A \cap B}$ is $\mu$-integrable.

and


 * $\ds \int \paren {f \cdot \chi_{A \cap B} + g \cdot \chi_{A \cap B} } \rd \mu = \int f \cdot \chi_{A \cap B} \rd \mu + \int g \cdot \chi_{A \cap B} \rd \mu$

Rewrite:


 * $f \cdot \chi_{A \cap B} + g \cdot \chi_{A \cap B} = \paren {f + g} \cdot \chi_{A \cap B}$

From Integrable Function is A.E. Real-Valued, we have that:


 * $X \setminus A$ and $X \setminus B$ are $\mu$-null sets.

Then by Null Sets Closed under Countable Union, we have that:


 * $\paren {X \setminus A} \cup \paren {X \setminus B}$ is $\mu$-null.

So, from Complement of Intersection, we have:


 * $X \setminus \paren {A \cap B}$ is $\mu$-null.

So if $x \in X$ has:


 * $\map {\paren {f + g} } x \map {\chi_{A \cap B} } x \ne \map {\paren {f + g} } x$

we have:


 * $\map {\chi_{A \cap B} } x = 0$

and:


 * $x \in X \setminus \paren {A \cap B}$, which is $\mu$-null.

So:


 * $\paren {f + g} \cdot \chi_{A \cap B} = f + g$ $\mu$-almost everywhere.

So from A.E. Equal Positive Measurable Functions have Equal Integrals: Corollary, we have that:


 * $f + g$ is $\mu$-integrable

and:


 * $\ds \int \paren {f + g} \cdot \chi_{A \cap B} \rd \mu = \int \paren {f + g} \rd \mu$

Similarly we have:


 * $f \cdot \chi_{A \cap B} = f$ $\mu$-almost everywhere.

So from A.E. Equal Positive Measurable Functions have Equal Integrals: Corollary, we have:


 * $\ds \int f \cdot \chi_{A \cap B} \rd \mu = \int f \rd \mu$

Since we also have:


 * $g \cdot \chi_{A \cap B} = g$ $\mu$-almost everywhere

we also get:


 * $\ds \int g \cdot \chi_{A \cap B} \rd \mu = \int g \rd \mu$

Putting it all together we get:


 * $\ds \int \paren {f + g} \rd \mu = \int f \rd \mu + \int g \rd \mu$