airo 25(1):

Research Article

Reimagining Asteroid Risk Assessment: A Comparative Review of Advanced Machine Learning Techniques

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  • @ARTICLE{10.4108/airo.9142,
    author={Kuldeep Vayadande and Dnyaneshwar M. Bavkar and Ishwari Rohit Raskar and Umar Mubarak Mulani and Jyoti Kanjalkar and Rajashree Tukaram Gadhave and Preeti Bailke and Yogesh Bodhe and Ajit R. Patil},
    title={Reimagining Asteroid Risk Assessment: A Comparative Review of Advanced Machine Learning Techniques},
    journal={EAI Endorsed Transactions on AI and Robotics},
    volume={4},
    number={1},
    publisher={EAI},
    journal_a={AIRO},
    year={2025},
    month={6},
    keywords={Asteroid Impact, Celestial Dynamics, High Dimensional Data, Risk Assessment of Impact, NEAs, Planetary Defense, Machine Learning, Space Security, Variational Quantum Classifier, VQC, Model Compression},
    doi={10.4108/airo.9142}
}
  • Kuldeep Vayadande
    Dnyaneshwar M. Bavkar
    Ishwari Rohit Raskar
    Umar Mubarak Mulani
    Jyoti Kanjalkar
    Rajashree Tukaram Gadhave
    Preeti Bailke
    Yogesh Bodhe
    Ajit R. Patil
    Year: 2025
    Reimagining Asteroid Risk Assessment: A Comparative Review of Advanced Machine Learning Techniques
    AIRO
    EAI
    DOI: 10.4108/airo.9142
Kuldeep Vayadande1,*, Dnyaneshwar M. Bavkar2, Ishwari Rohit Raskar3, Umar Mubarak Mulani4, Jyoti Kanjalkar1, Rajashree Tukaram Gadhave5, Preeti Bailke1, Yogesh Bodhe6, Ajit R. Patil7
  • 1: Vishwakarma Institute of Technology
  • 2: MGM College of Engineering & Technology
  • 3: MIT Art Design and Technology University
  • 4: KJ College of Engineering and Technology
  • 5: Pillai HOC College of Engineering and Technology
  • 6: Government Polytechnic
  • 7: Bharati Vidyapeeth's College of Engineering
*Contact email: kuldeep.vayadande1@vit.edu

Abstract

The escalating discovery rate of Near-Earth Asteroids (NEAs) has intensified the need for advanced computational frameworks capable of evaluating their impact risks with high precision. Traditional machine learning models, while foundational for early NEA classification and trajectory prediction, increasingly falter when confronted with the intricate, high-dimensional dynamics of asteroid motion. This limitation underscores the necessity for sophisticated techniques that reconcile computational efficiency with predictive accuracy across large, multi-dimensional datasets. This review systematically evaluates state-of-the-art machine learning algorithms—including quantum-enhanced models, hybrid quantum-classical frameworks, and lightweight convolutional neural networks (CNNs)—for their efficacy in asteroid risk assessment. By analyzing outcomes from recent studies, we contrast performance metrics such as accuracy, computational cost, and scalability. For instance, Quantum K-Nearest Neighbors (QKNN) demonstrates a 15% accuracy improvement over classical counterparts in high-dimensional data classification, while XGBoost achieves 99.99% precision in asteroid diameter prediction. Lightweight CNNs, such as MobileNetV1, further enable real-time processing on resource-constrained platforms like CubeSats, reducing latency by 30%.

Keywords
Asteroid Impact, Celestial Dynamics, High Dimensional Data, Risk Assessment of Impact, NEAs, Planetary Defense, Machine Learning, Space Security, Variational Quantum Classifier, VQC, Model Compression
Received
2025-03-21
Accepted
2025-05-07
Published
2025-06-02
Publisher
EAI
http://dx.doi.org/10.4108/airo.9142

Copyright © 2025 K. Vayadande et al., licensed to EAI. This is an open access article distributed under the terms of the CC BY-NCSA 4.0, which permits copying, redistributing, remixing, transformation, and building upon the material in any medium so long as the original work is properly cited.

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