Design and Development of Neuroevolutionary Algorithms for Cyber Security and Optimizing AI Models through Genetic Programming

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Published: Jan 25, 2024
DOI: https://doi.org/10.52783/jes.662
Keywords:
Advanced Neuroevolutionary Genetic Algorithm, ANGA, Cybersecurity Optimization, Genetic Algorithms, Neuroevolutionary Algorithms, Hyperparameter Optimization.

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Dharmesh Dhabliya, Araddhana Arvind Deshmukh, Riddhi R. Mirajkar, Bireshwar Ganguly, Shilpa Sharma, Shailesh P. Bendale,

Abstract

Different methods have been created to make optimization processes more efficient and effective, which is a big step forward in the area of evolutionary optimization. This abstract talks about four well-known methods: Neuroevolution of Augmenting Topologies (NEAT), Genetic Algorithms (GAs), Genetic Programming (GP), and Advanced Neuroevolutionary Genetic Algorithm (ANGA). It focuses on important performance indicators like Fitness Metrics, Generalization, Efficiency and Speed, and Overall Performance. With scores of 90% in Fitness Metrics and 88% in Generalization, NEAT, a neuroevolutionary program, shows strong success in competitive tasks. With an 80% score, it does poorly in Efficiency and Speed, though. GAs are known for using a population-based method. They do very well in Efficiency and Speed (90%), but they do a little worse in Fitness Metrics and Generalization (89% and 85%, respectively). With a focus on updated computer programs, GP gets marks that are equal in Fitness Metrics, Generalization, and Efficiency and Speed (88%, 85%, and 85%, respectively). The new ANGA algorithm stands out as a top worker, doing exceptionally well in all tests. ANGA gets great marks of 93% in Fitness Metrics, 94% in Generalization, and 93% in Efficiency and Speed. This shows how well it can optimize everything. Overall Performance score of 97.78% shows how well it works as a whole, making ANGA a potential method for genetic optimization.

Article Details

Issue
Vol. 19 No. 3 (2023)
Section
Articles
Creative Commons License

This work is licensed under a Creative Commons Attribution-NoDerivatives 4.0 International License.

Author Biography

Dharmesh Dhabliya, Araddhana Arvind Deshmukh, Riddhi R. Mirajkar, Bireshwar Ganguly, Shilpa Sharma, Shailesh P. Bendale,

1Dharmesh Dhabliya,

2Dr Araddhana Arvind Deshmukh, 

3Riddhi R. Mirajkar,

4Dr. Bireshwar Ganguly,

5Dr. Shilpa Sharma,

6Dr. Shailesh P. Bendale,

1Professor, Department of Information Technology, Vishwakarma Institute of Information Technology, Pune, Maharashtra, India Email: dharmesh.dhabliya@viit.ac.in

2Professor, Department of Computer Science & Information Technology (Cyber Security), Symbiosis Skill and Professional University, Kiwale, Pune, aadeshmukhskn@gmail.com

3Department of Information Technology, Vishwakarma Institute of Information Technology ,Pune, India. Email: riddhi.mirajkar@viit.ac.in

4Assistant Professor, Department of Computer Science and Engineering, Rajiv Gandhi College of Engineering, Research and Technology, Chandrapur, Maharashtra, India. Email: bireshwar.ganguly@gmail.com

5Assistant Professor, Symbiosis Law School, Nagpur Campus, Symbiosis International (Deemed University), Pune, India. Email: shilpasharma@slsnagpur.edu.in

6Head and Assistant Professor, Department of Computer Engineering, NBN Sinhgad School of Engineering, Pune, Maharashtra, India. Email: bendale.shailesh@gmail.com

Copyright © JES 2023 on-line : journal.esrgroups.org

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