Log-Laplace Nuggets for Fully Bayesian Fitting of Spatial Extremes Models to Threshold Exceedances

Referee: [§4] §4 (preservation of extremal dependence): The claim that the multiplicative log-Laplace nugget leaves the tail dependence unchanged requires an explicit demonstration that P(nugget dominates exceedance) → 0 uniformly as u → ∞. The exponential tails of the log-Laplace distribution make this non-automatic; the proof must supply the necessary restrictions on the nugget rate parameter relative to the tail index of the scale mixture (e.g., for Gaussian scale mixtures). Without these bounds the “broad class” statement is not fully substantiated and the modeling justification is weakened.

Authors: We agree that the preservation result requires a more explicit demonstration to fully substantiate the claim for the broad class of scale-mixture processes. The current Section 4 establishes preservation of the extremal dependence structure via the multiplicative construction, but we will add a dedicated lemma providing the uniform convergence argument. Specifically, we will show that under the restriction λ > ξ (where λ is the rate parameter of the log-Laplace nugget and ξ denotes the tail index of the underlying scale mixture), P(nugget dominates exceedance) → 0 uniformly as u → ∞. This condition will be stated clearly for Gaussian and other scale mixtures, strengthening the modeling justification without altering the core result. revision: yes

Referee: [§3.2] §3.2 (conditional independence construction): The derivation that the censored likelihood factors into independent univariate terms is stated to follow directly from the multiplicative construction and site-wise independence of the nugget. Please confirm that the censoring threshold is applied after multiplication and that no additional dependence is introduced through the scale-mixture component; an explicit statement of the resulting univariate density (including the form of the log-Laplace contribution) would strengthen the claim.

Authors: We confirm that the censoring threshold u is applied after multiplication by the independent log-Laplace nugget at each site. The scale-mixture component is shared across sites but does not introduce additional dependence in the censored likelihood because the nuggets are independent and multiplicative. The joint censored likelihood therefore factors exactly into the product of univariate terms. In the revised Section 3.2 we will state the resulting univariate density explicitly: for an exceedance at site i, the density is f_{Y_i}(y) = ∫ f_{scale-mixture}(y / ν) f_{log-Laplace}(ν) dν (with appropriate adjustment for the censored case below u), where the log-Laplace contribution appears directly in the integrand. This explicit form will be added to remove any ambiguity. revision: yes

Referee: [§5] Simulation studies (§5): The reported preservation of dependence is assessed only qualitatively. Quantitative checks (e.g., differences in extremal coefficients or stable tail dependence functions between the latent and nugget-augmented processes across a range of nugget parameters) are needed to confirm that the approximation error remains negligible for the parameter values used in the precipitation application.

Authors: We acknowledge that the simulation studies currently rely on qualitative visual comparisons. In the revised Section 5 we will add quantitative assessments, including tables reporting the maximum absolute differences in extremal coefficients and the integrated squared difference in stable tail dependence functions between the latent process and the nugget-augmented process, evaluated over a grid of nugget parameters that includes the values used in the precipitation application. These checks will confirm that the approximation error remains negligible in the relevant regime. revision: yes