Conditional Density Estimation with Neural Networks for Bias Correction of Multivariate Climate Model Data

Global Climate Models (GCMs) are numerical models that simulate complex physical processes within the Earth's climate system, and are essential for understanding and predicting climate change. However, GCMs suffer from systemic biases due to assumptions about and simplifications made to the underlying physical processes. GCM output therefore needs to be bias corrected before it can be used for future climate projections. Most common bias correction methods, however, cannot preserve spatial, temporal, or inter-variable dependencies. We propose a new bias correction method based on conditional density estimation for the simultaneous bias correction of daily precipitation and maximum temperature data obtained from gridded GCM spatial fields. The Vecchia approximation is employed to preserve dependencies in the data, and conditional density estimation is carried out using semi-parametric quantile regression. Illustration on historical data from 1951-2014 over two 5 x 5 spatial grids in the US indicate that our method can preserve key marginal and joint distribution properties of precipitation and maximum temperature, and predictions obtained using our approach are better calibrated compared to predictions using asynchronous quantile mapping and canonical correlation analysis, two commonly used alternative bias correction approaches.