I am studying the problem of how an expected utility maximizer should optimally form a portfolio of uncorrelated Bernoullis.
Fix an increasing sequence of $n$ numbers in $(0,1)$, $0<p_1<\dots<p_n<1$, to be interpreted as the parameters (probability of success) of a vector of independent Bernoulli random variables.
Given any $1\leq m\leq n$, we can define a random variable $S_m$ which counts the number of successes restricting to the subvector $p_m<\dots<p_n$. $S_m$ is supported in $\{0,\dots,n-m+1\}$ and is distributed according to a Poisson-Binomial $(p_i)_{i=m}^n$. In my application $S_m$ represents the ``payoff" of a risky portfolio.
Suppose that by choosing $m\in\{1,\dots,n\}$ the individual obtains a payoff of $$R_m=S_m+v(m-1)$$ where the term $v(m-1)$ represents the returns of a safe asset, for some $v\in (0,1)$. Consider the problem of maximizing the function
$$m\mapsto\mathbb{E}[u(R_m)]$$
for different choices of an increasing $u:[0,n]\to\mathbb{R}$. If $u$ is linear or convex (risk loving and risk neutrality) and $v<\frac{\sum_{i=1}^n p_i}{n}$, clearly the solution will be to choose $m=1$. Considering a concave $u$ is more interesting because, as $m$ decreases, the variables $S_m$ are such that both their mean and their variance increases. Hence, one has a trade off between enlarging the support of the portfolio and accepting more risk.
Q1 do you know any results about this problem?
The main problem working with the Poisson-Binomial to me is the combinatorics involved with its pmf and cdf. Hence, it would be nice to have a ``smooth" analog of the problem. In particular, replace the vector of $p$'s with a distribution over $[0,1]$ and let $F$ be its cdf.
Q2 How can we define an analog to the $S_m$'s random variables?
The idea would be that, by selecting a quantile of $F$, $q\in [0,1]$, one restricts to the Bernoulli's with parameter $p\geq q$. Hence, to each $q$, one should associate a random variable with support in $[0,1-F(q)]$. How to do this in a meaninful way? The problem of taking averages of the subfamily of Bernoulli's is that a law of large number kicks in (Law of large numbers for a continuum of Bernoullis) hence, the random variable is degenerate and the trade off above disappears.
