Search this site
Embedded Files
Skip to main content
Skip to navigation
Julia Briden
Home
About
Projects
Publications
Constraint-Informed Learning for Warm Starting Trajectory Optimization
Improving Computational Efficiency for Powered Descent Guidance
Transformer-based Atmospheric Density Forecasting
Impact of Space Weather on Space Assets and Satellite Launches
Risk Guarantees for Integrated Targeting and Guidance
Compositional Diffusion Models for Powered Descent Trajectory Generation
Julia Briden
Home
About
Projects
Publications
Constraint-Informed Learning for Warm Starting Trajectory Optimization
Improving Computational Efficiency for Powered Descent Guidance
Transformer-based Atmospheric Density Forecasting
Impact of Space Weather on Space Assets and Satellite Launches
Risk Guarantees for Integrated Targeting and Guidance
Compositional Diffusion Models for Powered Descent Trajectory Generation
More
Home
About
Projects
Publications
Constraint-Informed Learning for Warm Starting Trajectory Optimization
Improving Computational Efficiency for Powered Descent Guidance
Transformer-based Atmospheric Density Forecasting
Impact of Space Weather on Space Assets and Satellite Launches
Risk Guarantees for Integrated Targeting and Guidance
Compositional Diffusion Models for Powered Descent Trajectory Generation
Transformer-based Atmospheric Density Forecasting
GitHub Repositories Referenced in this Work
GitHub - timeseriesAI/tsai: Time series Timeseries Deep Learning Machine Learning Pytorch fastai | State-of-the-art Deep Learning library for Time Series and Sequences in Pytorch / fastai
Time series Timeseries Deep Learning Machine Learning Pytorch fastai | State-of-the-art Deep Learning library for Time Series and Sequences in Pytorch / fastai - GitHub - timeseriesAI/tsai: Time ...
Transformer-based Atmospheric Density Forecasting
As the peak of the solar cycle approaches in 2025 and the ability of a single geomagnetic storm to significantly alter the orbit of Resident Space Objects (RSOs), techniques for atmospheric density forecasting are vital for space situational awareness. While linear data-driven methods, such as dynamic mode decomposition with control (DMDc), have been used previously for forecasting atmospheric density, deep learning-based forecasting has the ability to capture nonlinearities in data. By learning multiple layer weights from historical atmospheric density data, long-term dependencies in the dataset are captured in the mapping between the current atmospheric density state and control input to the atmospheric density state at the next timestep. This work improves upon previous linear propagation methods for atmospheric density forecasting, by developing a nonlinear transformer-based architecture for atmospheric density forecasting. Empirical NRLMSISE-00 and JB2008, as well as physics-based TIEGCM atmospheric density models are compared for forecasting with DMDc and with the transformer-based propagator.
Full Paper
Google Sites
Report abuse
Page details
Page updated
Google Sites
Report abuse
