Avancee-1 Mission and SaDoD Method: LiDAR-based stimulated atomic
disintegration of space debris (SaDoD) using Optical Neural Networks
- URL: http://arxiv.org/abs/2105.13485v1
- Date: Thu, 27 May 2021 22:44:28 GMT
- Title: Avancee-1 Mission and SaDoD Method: LiDAR-based stimulated atomic
disintegration of space debris (SaDoD) using Optical Neural Networks
- Authors: Manuel Ntumba, Saurabh Gore
- Abstract summary: This paper discusses Avancee-1 Mission, LiDAR-based space debris removal using Optical Neural Networks (ONN) to optimize debris detection and mission accuracy.
The results show that orbital debris undergoes the most intense degradation at low altitudes and higher temperatures.
The SaDoD Method can be implemented with other techniques, but especially for the Avancee-1 Mission, the SaDoD was implemented with LiDAR technologies and Optical Neural Network algorithms.
- Score: 0.0
- License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
- Abstract: The surface degradation of satellites in Low Earth Orbit (LEO) is affected by
Atomic Oxygen (AO) and varies depending on the spacecraft orbital parameters.
Atomic oxygen initiates several chemical and physical reactions with materials
and produces erosion and self-disintegration of the debris at high energy. This
paper discusses Avancee-1 Mission, LiDAR-based space debris removal using
Optical Neural Networks (ONN) to optimize debris detection and mission
accuracy. The SaDoD Method is a Stimulated Atomic Disintegration of Orbital
Debris, which in this case has been achieved using LiDAR technology and Optical
Neural Networks. We propose Optical Neural Network algorithms with a high
ability of image detection and classification. The results show that orbital
debris has a higher chance of disintegration when the laser beam is coming from
Geostationary Orbit (GEO) satellites and in the presence of high solar
activities. This paper proposes a LiDAR-based space debris removal method
depending on the variation of atomic oxygen erosion with orbital parameters and
solar energy levels. The results obtained show that orbital debris undergoes
the most intense degradation at low altitudes and higher temperatures. The
satellites in GEO use Optical Neural Network algorithms for object detection
before sending the laser beams to achieve self-disintegration. The SaDoD Method
can be implemented with other techniques, but especially for the Avancee-1
Mission, the SaDoD was implemented with LiDAR technologies and Optical Neural
Network algorithms.
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