Fix $n > 0$, and consider the space $\cal P$ of probability functions defined over the Boolean closure of a fixed $\cal S = \{ s_1, \ldots, s_n \}$. The *Brier score* of $P \in \cal P$ at $s_i \in \cal S$ is given by 
$$BS(P,s_i) = \sum_{1 \leq j \leq n} (P(s_i) - \mathbb 1_{i = j})^2,$$
where $\mathbb 1_{i=j}$ is 1 if $i=j$ and 0 otherwise. The Brier score is *strictly proper* in that, for any $P \neq Q \in \cal P$, 

$$\sum_i P(s_i) BS(P,s_i) < \sum_i P(s_i) BS(Q,s_i).$$

Fix $\lambda_i$, with $(1 \leq i \leq n)$, $\lambda_i > 0$. The following variant of the Brier score is also proper: 
$$BS_\lambda(P,s_i) = \sum_{1 \leq j \leq n} \lambda_j \cdot (P(s_j) - \mathbb 1_{i = j})^2.$$
This is essentially because
$$a\cdot(1-x)^2 + (1-a)\cdot x^2$$ takes its minimum at $x=a$, and because 
$$\sum_i P(s_i) \cdot BS_\lambda(Q,s_i) = \sum_i \lambda_i \left(P(s_i)\cdot(1-Q(s_i))^2 + (1 - P(s_i))\cdot Q(s_i)^2\right).$$

Now, let $\cal F$ denote the Boolean closure of $\cal S$, and set 
$$BS_{\cal F}(P,s_i) = \sum_{X \in \cal F} (P(X) - \chi_X(s_i))^2,$$
where $\chi_X$ is the characteristic function of $X$. It is easy to see that $BS_{\cal F}$ is also strictly proper. 

But again, fix $\lambda_X > 0$, $X \in \cal F$, and set
$$BS^\lambda_{\cal F}(P,s_i) = \sum_{X \in \cal F} \lambda_X \cdot(P(X) - \chi_X(s_i))^2.$$

Is $BS^\lambda_{\cal F}$ proper? 

If so, given $\lambda_X > 0$, $X \in \cal F$, is it possible to find $\mu_i > 0$, $1 \leq i \leq n$ such that: 

$$BS^\lambda_{\cal F}(P,s_i) = BS^\mu(P,s_i).$$

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**Update**: The answer to the first question is *yes*, since we can equally well write down the expectation of  $BS^\lambda_{\cal F}(Q,s_i)$ relative to $P$ as

$$\sum_{X \in \cal F} \lambda_X \cdot \left(P(X)\cdot(1 - Q(X))^2 + (1-P(X)\cdot Q(X)^2\right).$$  

The remaining question then is: 

Given $\lambda_X > 0$, $X \in \cal F$, is it possible to find $\mu_i > 0$, $1 \leq i \leq n$ such that: 

$$BS^\lambda_{\cal F}(P,s_i) = BS^\mu(P,s_i).$$