The average size of downward closed family of the subsets of $[n]$ is at most $n/2$?

Question

I learned that the average size in any ideal of subsets of $[n]$ is at most $n/2$, but I think the downward closed family of the subsets of $[n]$ also satisfied. I want to know how to proof it or it is wrong. A downward closed family $\mathcal{F}$ means for any $A \in \mathcal{F}, B \subseteq A$, we have $B \in \mathcal{F}$, and the ideal's definition is here https://en.wikipedia.org/wiki/Ideal_(set_theory).

Answer 1

Here is a pedestrian answer. If $\def\cF{\mathcal F}\cF$ is a downward closed subset of $\mathcal P([n])$, we have

$$\frac1{|\cF|}\sum_{A\in\cF}|A|=\sum_{i\in[n]}\Pr_{A\in\cF}[i\in A].$$

Now, for any $i\in[n]$,

$$\Pr_{A\in\cF}[i\in A]\le\frac12,$$

because the mapping $A\mapsto A\smallsetminus\{i\}$ provides an injection

$$\{A\in\cF:i\in A\}\to\{A\in\cF:i\notin A\}.$$

Answer 2

This is true and indeed, much more can be said: if $\mathcal F$ is a downward closed family of subsets of $[n]$, then $$ \frac1{|\mathcal F|}\, \sum_{F\in\mathcal F} |F| \le \frac12\, \log_2|\mathcal F|; $$ equivalently, if $A\subseteq\{0,1\}^n$ is a downset, then $$ \frac1{|A|}\, \sum_{a\in A} w(a) \le \frac12\, \log_2 |A|, $$ where $w(a)$ is the number of non-zero components of $a$. This is Theorem 3 of the linked paper (see also the abstract).