@article {bnh-5008, title = {Evaluation and calibration of a high-resolution soil moisture product for wildfire prediction and management}, journal = { Agricultural and Forest Meteorology}, volume = {264}, year = {2019}, month = {01/2019}, pages = {12}, chapter = {27}, abstract = {

Soil moisture deficit is a key variable used in operational fire prediction and management applications. In Australia, operational fire management practices use simple, empirical water balances models to estimate soil moisture deficit. The Bureau of Meteorology has recently developed a prototype, high-resolution, land surface modelling based, state-of-the-art soil moisture analyses for Australia. The present study examines this new product for use in operational fire prediction and management practices in Australia. The approach used is twofold. First, the new soil moisture product is evaluated against observations from ground based networks. Among the results, the mean Pearson{\textquoteright}s correlation for surface soil moisture across the three in-situ networks is found to be between 0.78 and 0.85. Secondly, the study evaluate a few different calibration methods to facilitate the ready utilization of the new soil moisture product in the current operational fire prediction framework. The calibration approaches investigated here are: minimum-maximum matching, mean-variance matching and, cumulative distribution function matching. Validation of the calibrated products using extended triple collocation technique shows that the minimum-maximum method has the highest skill. Evaluation of the calibrated products against MODIS fire radiative power data highlights that large fires correspond to a drier soil in minimum-maximum outputs compared to other calibration results and the current operational method.

}, keywords = {Calibration, Fire danger rating, Land surface model, Soil moisture deficit, Triple collocation, Verification}, doi = {10.1016/j.agrformet.2018.09.012}, url = {https://www.sciencedirect.com/science/article/pii/S0168192318303071}, author = {Vinod Kumar and Imtiaz Dharssi} }