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Valid inference under the asymmetric Laplace likelihood

The problem

The asymmetric Laplace distribution (ALD) is a convenient working likelihood for quantile regression: its mode-as-quantile and the check-loss connection make Bayesian computation straightforward (Yu and Moyeed, 2001). But it is misspecified for almost any real data-generating process, and a misspecified likelihood produces a posterior whose spread is the wrong asymptotic variance for the quantile-regression estimator. Naive credible intervals from such a posterior do not have correct frequentist coverage.

The correction

Yang, Wang and He (2016) restore validity with a multiplicative sandwich that re-uses the posterior covariance as the “bread”:

\[ V_\text{adj} = \Sigma_\text{post}\, G\, \Sigma_\text{post}, \]

where \(\Sigma_\text{post}\) is the posterior covariance of the fixed effects and \(G\) is the meat — the variance of the asymmetric-Laplace working-likelihood score. With score \(s_i = \sigma^{-1} x_i\,(\tau - \mathbf{1}\{r_i<0\})\) on the conditional residuals \(r_i\), the meat is \(G = \sigma^{-2}\sum_g\big(\sum_{i\in g} x_i\psi_i\big)\big(\cdot\big)'\) (cluster-robust on the grouping factor; the default), or its independence analogue.

Using \(\Sigma_\text{post}\) as the bread is what makes this correct for a mixed model: the posterior covariance already encodes the multilevel pooling, so the adjustment keeps the random-effect contribution to fixed-effect uncertainty while fixing the misspecified ALD scale. Under correct specification \(G \approx \Sigma_\text{post}^{-1}\) and the correction reduces to \(\approx \Sigma_\text{post}\).

vcov(fit, adjusted = TRUE)    # corrected (multiplicative, cluster meat)
vcov(fit, adjusted = FALSE)   # naive posterior covariance
confint(fit, adjusted = TRUE)

Why not the plain Koenker sandwich?

The textbook fixed-effects sandwich \(\tau(1-\tau)D_1^{-1}D_0D_1^{-1}/n\) (available internally as compute_ywh_sandwich() and validated against quantreg) is computed on residuals with the random effects removed, so it drops the between-cluster variance and under-covers the mixed-model fixed effects. A simulation bake-off (tools/bakeoff.R) confirmed this: across homoscedastic and heteroscedastic two-level designs at several quantiles, the Koenker form covered the fixed intercept at only 0.72–0.92, while the multiplicative form above covered at 0.95–1.00 — at or just above nominal everywhere.

Scope and caveats

References

Yang, Y., Wang, H. J. and He, X. (2016). Posterior inference in Bayesian quantile regression with asymmetric Laplace likelihood. International Statistical Review, 84(3), 327-344.

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