Abstract
We have used lightning information to augment the precipitation estimation from remotely sensed imagery using an artificial neural network cloud classification system (PERSIANN-CCS). Co-located lightning data are used to segregate cloud patches, segmented from Geostationary Operational Environmental Satellite (GOES)-12 infrared (IR) data, into either electrified patches (ECPs) or nonelectrified patches (NECPs). A set of features is extracted separately for the ECPs and NECPs. Features for the ECPs include a new feature corresponding to the number of flashes that occur within a 15 minute window around the time of the nominal scan of the satellite IR images of the cloud patches. The cloud patches are classified and clustered using a self-organizing maps (SOM) neural network. Then, brightness temperature and rain rate (T-R) relationships are derived for different clusters. Rain rates are estimated for the cloud patches based on their representative (T-R) relationship. The equitable threat scores (ETS) of the daily and hourly precipitation estimates at a range of rain rate thresholds show that incorporating lightning information can improve categorical precipitation estimation in the winter and fall seasons. In the winter, the ETS improvement is almost 15% for the daily and 12% for the hourly rainfall estimates (at thresholds below 15 mm hour-1). During the same period, there is also a drop in the false alarm ratio (FAR) and a corresponding increase in the probability of detection (POD) at most threshold levels. During the summer and spring seasons, no categorical significant improvements have been noted, except for the BIAS scores for the hourly rainfall estimates at higher thresholds (above 5 mm hour-1) in the summer months. A quantitative evaluation in terms of the root mean squared error (RMSE) and correlation coefficient (CORR) shows that the incorporation of lightning data does improve rainfall estimation over all seasons with the most improvement (around 11-13% CORR improvement) occurring during the winter. We speculate that during the winter, more of the ice processes are packed into a thinner stratiform layer with lower cloud tops and freezing levels. Hence, more of the ice contributes to precipitation on the ground. We also expect that information from lightning, related to the ice microphysics processes, provides surrogate information about the rain rate.
Original language | English |
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Pages (from-to) | 5796-5811 |
Number of pages | 16 |
Journal | International Journal of Remote Sensing |
Volume | 34 |
Issue number | 16 |
DOIs | |
State | Published - Aug 2013 |
Funding
This research was sponsored by the NASA Applied Sciences Program under Grant NNS06AA98B and the NOAA Office of Atmospheric Research via Grant NA07OAR4170517. We also thank the PERSIANN group at UC Irvine for the PERSIANN-CCS data and the helpful discussions about their methodology. Valentine Anantharaj is also supported by the Oak Ridge Leadership Computing Facility under the auspices of the Office of Advanced Scientific Computing Research, Office of Science, US Department of Energy under Contract No. DE-AC05-00OR22725 and Contract No. DE-AC05-00OR22725 with UT-Battelle, LLC.
Funders | Funder number |
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NOAA Office of Atmospheric Research | NA07OAR4170517 |
Oak Ridge National Laboratory | |
US Department of Energy | |
National Aeronautics and Space Administration | NNS06AA98B |
Office of Science | |
Advanced Scientific Computing Research |