Machine Learning Approach to Classify Precipitation Type from A Passive
Microwave Sensor
Abstract
Precipitation flag (precipitating or not; stratiform or convective) is a
key parameter for us to make betterretrieval of precipitation
characteristics as well as to understand the cloud-precipitation
physicalprocesses. The Global Precipitation Measurement (GPM) Core
Observatory’s Microwave Imager (GMI)and Dual-Frequency Precipitation
Radar (DPR) together provide ample information on globalprecipitation
characteristics. As an active sensor in particular, DPR provides an
accurate precipitationflag assignment, while passive sensors like GMI
were traditionally believed not to be able to tell apartprecipitation
types. Using collocated precipitation flag assignment from DPR as the
“truth”, this project employs machinelearning models to train and test
the predictability and accuracy of using passive GMI-only
observationstogether with ancillary atmosphere information from
reanalysis. Precipitation types are classified intothe following
classes: convective, stratiform, convective-stratiform mixed, no
precipitation, and otherprecipitation. Sub-sampling with different
probabilities is employed to construct a balanced trainingdataset. A
variety of classification algorithms are tested, including Support
Vector Machines, NaiveBayes, Random Forests, Gradient Boosting, and
Neural Networks (Multilayer Perceptron Network), andtheir results are
evaluated and compared. The trained model has ~ 85% of
prediction accuracy for everytype of precipitation. High-frequency
channels (166 GHz and 183 GHz channels) and 166 GHzpolarization
difference are found among the most important factors that contribute to
the modelperformance, which shed light on future instrument channel
selection.