Let $F(A)$ be a function on an ordered set $A$ that outputs a set $B$ such that the elements of $B$ are determined as follows.

$A_i\in B$ if $A_i > A_{i-1}, A_{i-2}.... ,A_1$
That is, an element is in B if it is larger than all of its preceding elements.

Given that an ordered set A has cardinality $n$, what is the expected value of the cardinality of F(A)?

I have a recursive solution; if $A$ has cardinality $n = 1$, $E[|F(A)|] = 1$ When looking at $n = 2$ it's equivalent to taking A and randomly inserting a larger element $a_2$ into $A$. From {$a1$} we have either {$a_1, a_2$} or {$a_2, a_1$}. We can reduce the case into either $E[|F(1)|] + 1$ or $1$ all with equal probability giving us an expected value of $\frac{1}{2}(E[|F(1)|] + 1 + 1) = 1 + \frac{1}{2}(E[|F(1)|])$ We can extend this to any cardinality $n$ as just expressing it as $1 + \frac{1}{n}(E[|F(n-1)|] + E[|F(n-2)|] ... + E[|F(1)|])$

I'm asking if there's a solution that does not rely on knowing the expected values of $F(1)$ to $F(n-1)$