stan_polr: Bayesian ordinal regression models via Stan

A stanreg object is returned for stan_polr.

A stanfit object (or a slightly modified stanfit object) is returned if stan_polr.fit is called directly.

The stan_polr function is similar in syntax to polr but rather than performing maximum likelihood estimation of a proportional odds model, Bayesian estimation is performed (if algorithm = "sampling") via MCMC. The stan_polr function calls the workhorse stan_polr.fit function, but it is possible to call the latter directly.

As for stan_lm, it is necessary to specify the prior location of \(R^2\). In this case, the \(R^2\) pertains to the proportion of variance in the latent variable (which is discretized by the cutpoints) attributable to the predictors in the model.

Prior beliefs about the cutpoints are governed by prior beliefs about the outcome when the predictors are at their sample means. Both of these are explained in the help page on priors and in the rstanarm vignettes.

Unlike polr, stan_polr also allows the "ordinal" outcome to contain only two levels, in which case the likelihood is the same by default as for stan_glm with family = binomial but the prior on the coefficients is different. However, stan_polr allows the user to specify the shape and rate hyperparameters, in which case the probability of success is defined as the logistic CDF of the linear predictor, raised to the power of alpha where alpha has a gamma prior with the specified shape and rate. This likelihood is called “scobit” by Nagler (1994) because if alpha is not equal to \(1\), then the relationship between the linear predictor and the probability of success is skewed. If shape or rate is NULL, then alpha is assumed to be fixed to \(1\).

Otherwise, it is usually advisible to set shape and rate to the same number so that the expected value of alpha is \(1\) while leaving open the possibility that alpha may depart from \(1\) a little bit. It is often necessary to have a lot of data in order to estimate alpha with much precision and always necessary to inspect the Pareto shape parameters calculated by loo to see if the results are particularly sensitive to individual observations.

Users should think carefully about how the outcome is coded when using a scobit-type model. When alpha is not \(1\), the asymmetry implies that the probability of success is most sensitive to the predictors when the probability of success is less than \(0.63\). Reversing the coding of the successes and failures allows the predictors to have the greatest impact when the probability of failure is less than \(0.63\). Also, the gamma prior on alpha is positively skewed, but you can reverse the coding of the successes and failures to circumvent this property.