I have a question on the proof Durrett (p. $190$) gives for the uniqueness of the conditional expectation function.
If I understand his proof correctly, here is what I think it is saying:
Suppose $Y, Y'$ both satisfy the criteria to be a conditional expectation function for a random variable $X$ given a $\sigma$-algebra $\mathcal{A}$. Then if $A_{\epsilon} := \{ \omega \mid Y - Y' \geq \epsilon \}$, clearly $A_{\epsilon} \in \mathcal{A}$, and so by the criteria we have for conditional expectation, we have:
$$0 = \int \limits_{A_{\epsilon}} Y - Y' \,dP \geq \epsilon P(A_{\epsilon}) \geq 0$$ and this shows that $P(A_{\epsilon}) = 0$ for all $\epsilon > 0$.
Ok, then we note that $0 \leq P( \{\omega \mid Y - Y' > 0 \} ) = P(\bigcup \limits_{n =1}^{\infty} A_{\frac{1}{n}}) \leq \sum \limits_{n = 1}^{\infty} P(A_{\frac{1}{n}}) = \sum \limits_{n = 1}^{\infty} 0 = 0$. Thus, $P( \{\omega \mid Y - Y' \leq 0 \} ) = 1$, so $Y \leq Y'$ almost surely.
We can repeat the same proof switching $Y$ and $Y'$ to get $Y' \leq Y$ almost surely, thus they are equal almost surely.
My question:
I think the following proof is a much simpler one (using the fact that $\int \limits_{\Omega} X \,dP = 0 \implies X = 0$ almost surely). Is there any flaw in the argument below? If not, why did Durrett decide to do so many extra steps?
Since $\Omega \in \mathcal{A}$, we have $0 = \int \limits_{\Omega} Y - Y' \,dP$, and thus $Y - Y' = 0$ almost surely, so $Y = Y'$ a.s.
