I have a regression model (part of a larger hierarchical model) where I wish to try construct a regression using the residuals of a regression.
To simplify, say we have $j$ in $n$ observations, a $j \times r$ design matrix $X$, and corresponding coefficient vector $\beta$, such that \begin{equation*} y = X\beta + \epsilon \\ \epsilon \sim N(0, \sigma^2) \end{equation*}
Assuming we have equivalent observations and coefficients for each $k$ of $m$ subjects, we can write \begin{equation} y_k = X_k\beta_k + \epsilon_k \end{equation} The residuals, $\epsilon_k$ are of interest to me. I would thus like to try to model differences in the residuals between subjects, using a vector of $p$ subject-specific covariates, $z_k$. This is where things get confusing for me. Now we would have \begin{equation} \epsilon_k = z_k\psi_k \sim N(0,\sigma^2_k) \end{equation} I cannot place a prior on $z_k\psi_k$ though, since $z_k$ can vary arbitrarily. I then thought that perhaps the solution is to have a nested regression for the residuals, such that \begin{equation} \epsilon_k \sim N(z_k\psi_k,\sigma^2_k) \ \text{or} \\ \epsilon_k = z_k\psi_k + \tau_k, \ \ \tau_k\sim N(0, \sigma^2_k) \end{equation} However, this seems non-identifiable to me. If we don't restrict $\epsilon_k$, then the values of $X_k\beta_k$ and $\epsilon_k$ can exchange, and the likelihood would be equivalent. There seems to be no way to disentangle the effect of the two sets of covariates.
It seems to me that if I restrict $\beta_k$ to be the same across all subjects I have some chance, ie: \begin{equation} y_k = X_k\beta + \epsilon_k \end{equation} since this induces some shrinkage towards a global value, but I am unsure if this would be enough to allow me to infer these effects. Is there an alteration I can make, or an alternative approach that would make this tractable?
