Litcius/Paper detail

Utilizing Artificial Neural Networks for Entry Vehicle Aerodynamic Characterization

Zachary Ernst, Bradford E. Robertson, Dimitri N. Mavris

2024Journal of Spacecraft and Rockets12 citationsDOI

Abstract

Determining the dynamic stability of blunt body entry vehicles is a persistent engineering challenge, particularly in the low supersonic to subsonic flight regime where the behavior of the unsteady wake is a primary contributor. Dynamic stability quantities are determined by fitting measurements of a ballistic range campaign or a computational fluid dynamics (CFD) computational experiment to an assumed functional form in order to regress quasi-static stability coefficients. However, this data reduction process has many implicit assumptions that may not hold. This paper explores novel alternatives to the established methods for modeling blunt body aerodynamics. A six-degree-of-freedom CFD-in-the-loop flight model is used to run “virtual ballistic range tests,” fully capturing the relevant flow physics. Feed-forward and time-delay neural network models are fitted to the time-series trajectory and aerodynamic results, which can then be used to predict aerodynamic forces and moments. These models do not have a prescribed functional form and do not assume linearized aerodynamics. The models are evaluated for goodness-of-fit in their aerodynamic and trajectory prediction. The feed-forward neural network model resulted in a better prediction of the virtual ballistic range tests than a traditional database. The time-delay network had good open-loop performance but suffered from closed-loop instability.

Topics & Concepts

AerodynamicsArtificial neural networkAerospace engineeringCharacterization (materials science)Atmospheric entryComputer scienceEngineeringMaterials scienceArtificial intelligenceNanotechnologyAerodynamics and Fluid Dynamics ResearchComputational Fluid Dynamics and AerodynamicsAerospace and Aviation Technology