Scale‐Separated Dynamic Mode Decomposition and Ionospheric Forecasting
Abstract
We present a method for forecasting the foF2 and hmF2 parameters using modal decompositions from measured ionospheric electron density profiles. Our method is based on Dynamic Mode Decomposition (DMD), which provides a means of determining spatiotemporal modes from measurements alone. Our proposed extensions to DMD use wavelet decompositions that provide separation of a wide range of high‐intensity, transient temporal scales in the measured data. This scale separation allows for DMD models to be fit on each scale individually, and we show that together they generate a more accurate forecast of the time‐evolution of the F‐layer peak. We call this method the Scale‐Separated Dynamic Mode Decomposition (SSDMD). The approach is shown to produce stable modes that can be used as a time‐stepping model to predict the state of foF2 and hmF2 at a high time resolution. We demonstrate the SSDMD method on data sets covering periods of high and low solar activity as well as low, mid, and high latitude locations.
Document Details
- Document Type
- Pub Defense Publication
- Publication Date
- Aug 01, 2023
- Source ID
- 10.1029/2022rs007637
Entities
People
- Alexander T. Ihler
- Christopher W. Curtis
- Daniel Jay Alford-Lago
- Kate Zawdie
Organizations
- Naval Information Warfare Center Pacific
- Office of Naval Research
- San Diego State University
- United States Naval Research Laboratory
- University of California, Irvine