EAGER: North American Monsoon Prediction Using Causality Informed Machine Learning

Information

  • NSF Award
  • 2313689
Owner
  • Award Id
    2313689
  • Award Effective Date
    3/1/2023 - a year ago
  • Award Expiration Date
    2/29/2024 - 10 months ago
  • Award Amount
    $ 162,492.00
  • Award Instrument
    Standard Grant

EAGER: North American Monsoon Prediction Using Causality Informed Machine Learning

This research seeks better understanding of monsoon thunderstorm activity and precipitation in the Southwest. The project creates an innovative machine learning tool trained using regional numerical weather model output and satellite remote sensing data (the predictors) with respect to known thunderstorm cell locations and intensities detected by radar (the targets). The tool will be designed to extract important fundamental relationships between the predictors and targets that help explain the development and evolution of thunderstorms. After an intense training, validation and testing phase, the relationships will then be leveraged to generate better forecasts of the timing, severity and location of future thunderstorm events in the Southwest. The tool will be shared with the National Weather Service to help forecasters predict thunderstorm-related hazards such as large hail, flash flooding or wildfire ignition. This innovative approach will also provide a framework for improving operational meteorological and geophysical prediction systems and for guiding scientific field studies.<br/><br/>The project develops a probabilistic model to predict convective initiation, rain rates, and convective cell tracks during the wet phase of the North American Monsoon (NAM). Predictors of convection (e.g., relative humidity, convective available potential energy, precipitable water) will be collected from dynamic mesoscale model (High Resolution Rapid Refresh, University of Arizona-Weather Research Forecast model) analyses and forecasts and combined with new satellite-derived observations of soil moisture and surface temperature to produce a unique prediction tool. A novel machine learning approach – causality informed learning – will be applied to identify the most suitable predictors for further training in a neural network and to gain insight into the processes governing convective initiation and evolution. Hourly forecasts of precipitation occurrence, nature, and categorical rain rates will be produced operationally to guide forecasters and field research.<br/><br/>This award reflects NSF's statutory mission and has been deemed worthy of support through evaluation using the Foundation's intellectual merit and broader impacts review criteria.

  • Program Officer
    Chungu Luclu@nsf.gov7032927110
  • Min Amd Letter Date
    3/1/2023 - a year ago
  • Max Amd Letter Date
    3/1/2023 - a year ago
  • ARRA Amount

Institutions

  • Name
    Embry-Riddle Aeronautical University
  • City
    DAYTONA BEACH
  • State
    FL
  • Country
    United States
  • Address
    1 AEROSPACE BLVD
  • Postal Code
    321143910
  • Phone Number
    3862267695

Investigators

  • First Name
    Curtis
  • Last Name
    James
  • Email Address
    James61c@erau.edu
  • Start Date
    3/1/2023 12:00:00 AM
  • First Name
    Christopher
  • Last Name
    Hennon
  • Email Address
    Hennonc@erau.edu
  • Start Date
    3/1/2023 12:00:00 AM
  • First Name
    Ronny
  • Last Name
    Schroeder
  • Email Address
    ronny.schroeder@erau.edu
  • Start Date
    3/1/2023 12:00:00 AM
  • First Name
    Abd AlRahman
  • Last Name
    AlMomani
  • Email Address
    almomana@erau.edu
  • Start Date
    3/1/2023 12:00:00 AM

Program Element

  • Text
    Physical & Dynamic Meteorology
  • Code
    1525

Program Reference

  • Text
    EAGER
  • Code
    7916