N coins have probability $p_n = e^{-t_n/s}$ of heads, $t_n$ being specific for each coin. Coins 1 to m came up heads and m+1 to N came up tails. Now I'm trying to estimate $s$ using the Maximum Likelihood Method.
$L(s) = p_1 p_2 \dots p_m (1-p_{m+1})\dots(1-p_N)$
But this function is difficult to maximize. Do I have to resort to numerical methods?
As @Suvrit wrote in a comment, there's not always a solution. We have $$\frac{L'(s)}{L(s)} = \sum_{i\le m} \frac{t_i}{s^2} - \sum_{i>m} \frac{t_i}{s^2}\frac{p_i}{1-p_i} $$ $$=\sum_{i\le m} \frac{t_i}{s^2} - \sum_{i>m} \frac{t_i}{s^2}\left(\frac{1}{1-p_i}-1\right)=\sum_{i\le N} \frac{t_i}{s^2} - \sum_{i>m} \frac{t_i}{s^2}\left(\frac{1}{1-p_i}\right)=0$$ if \begin{equation} \sum_{i\le N} t_i = \sum_{i>m} t_i\frac{1}{1-p_i}. \end{equation} Let's consider the case $m=N-2=0$: $$(1-e^{-t_2/s})(1-e^{-t_1/s})(t_1+t_2)=t_2(1-e^{-t_1/s})+t_1(1-e^{-t_2/s})$$ Let $(t_1,t_2)=(1,1)$ and $u=1/s$, then $$(1-e^{-u})(1-e^{-u})(2)=(1-e^{-u})+(1-e^{-u})$$ $$(1-e^{-u})=1$$ which has no solution.
