Comment on hess-2023-45

Abstract

<strong class="journal-contentHeaderColor">Abstract.</strong> Long continuous time series of meteorological variables (i.e. rainfall, temperature and radiation) are required for applications such as derived flood frequency analyses. Observed time series are however generally too short, too sparse in space, or incomplete, especially at the sub-daily timestep. Stochastic weather generators overcome this problem by generating time series of arbitrary length. This study presents a major revision to an existing space-time hourly rainfall model based on a point alternating renewal process, now coupled to a k-NN resampling model for conditioned simulation of non-rainfall climate variables. The point based rainfall model is extended into space by the resampling of simulated rainfall events using a simulated annealing optimisation approach. Large station networks (<em>N</em> &gt; 50) are now able to be modelled with no significant loss in the spatial dependence structure. Modelling of non-rainfall climate variables, i.e. temperature, humidity and radiation, is achieved using a non-parametric knearest neighbour (k-NN) resampling approach, coupled to the space-time rainfall model via rainfall state. As input, a gridded daily observational dataset (HYRAS) was used. A final disaggregation step was then performed on all non-rainfall climate variables to achieve an hourly output temporal resolution. The proposed weather generator was tested on 400 catchments of varying size (50&ndash;20,000 km&sup2;) across Germany, comprising 699 sub-daily rainfall recording stations. Results indicate no major loss of model performance with increasing catchment size, and a generally good reproduction of observed climate and rainfall statistics.