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Attitude motion classification of resident space objects using light curve spectral analysis

Giorgio Isoletta, Roberto Opromolla, Giancarmine Fasano

2024Advances in Space Research10 citationsDOIOpen Access PDF

Abstract

• A light curve-based attitude motion classifier of RSO is proposed. • It relies on Lomb-Scargle Periodogram and Phase Dispersion Minimization techniques. • Extensive performance assessment is done using a synthetic light curves generator. • Impact of observation duration, object’s shape and attitude state, is investigated. • Additional tests on a public light curve database show good results on real data. The characterization of Earth-orbiting objects in terms of attitude motion, material composition, and shape is crucial for Space Domain Awareness. In this respect, light curves, i.e., graphs showing the brightness variation of space objects over a specific time interval, can be used to infer both their dynamical and physical properties. However, such light curve inversion problem is challenging due to measurement noise, data gaps, and the intrinsic difficulty in separating the multiple effects impacting on the object’s brightness. Existing light curve inversion methods rely on estimation filters exploiting data fusion, Machine Learning approaches, or are based on the analysis of the light-curve frequency spectra. Many of these approaches make assumptions about a-priori knowledge of target object’s characteristics, such as shape, size, surface reflective properties, and/or observation parameters, e.g., target’s orbit and observation geometry. In this framework, this paper presents an innovative architecture for the classification of the attitude motion of space objects using only photometric light curve data, not requiring any a-priori assumption or knowledge. The proposed architecture exploits the Lomb-Scargle Periodogram algorithm to retrieve a frequency spectrum from light curve measurements, and then performs the classification by analyzing the spectrum characteristics testing different candidate rotation periods through the Phase Dispersion Minimization method. The proposed classification algorithm is first tested using a light curve simulator, in which any complex geometric model and different surface properties can be generated. Finally, the method is applied to real light curves retrieved from a publicly available database to assess the classification performance.

Topics & Concepts

Motion (physics)Space (punctuation)Light curveSpectral analysisMotion analysisComputer sciencePhysicsComputer visionArtificial intelligenceMathematical analysisMathematicsAstronomyOperating systemSpectroscopyInertial Sensor and NavigationSatellite Image Processing and PhotogrammetryAstronomical Observations and Instrumentation