Volume 14 , Issue 2 , PP: 287-299, 2024 | Cite this article as | XML | Html | PDF | Full Length Article
K. Jayakumar 1 * , K. Sivakami 2 * , P. Logamurthy 3 , P. Sathiyamurthi 4 , N. Chandrasekaran 5
Doi: https://doi.org/10.54216/JCIM.140220
In the digital age, the safeguarding of information through effective cybersecurity measures is paramount. This paper presents the development of a robust cryptographic model tailored for cybersecurity applications. The background underscores the increasing prevalence of cyber threats and the necessity for advanced encryption techniques to ensure data confidentiality, integrity, and authenticity. The methodology involves the design and implementation of the cryptographic model using state-of-the-art algorithms and protocols. Rigorous testing and evaluation were conducted to assess the model's performance in various cyber environments. The results indicate that the proposed model significantly enhances security, demonstrating high resistance to common cyber-attacks with an average encryption time of 0.5 seconds for a 1MB file and a decryption accuracy rate of 99.9%. The model also achieved a data integrity verification success rate of 99.8% and an overall system efficiency improvement of 45% compared to existing models. The conclusion highlights the model's effectiveness and potential for broad application in securing digital communication, offering a substantial contribution to the field of cybersecurity.
Cryptographic Model , Cybersecurity , Data Confidentiality , Data Integrity , Encryption Techniques , Security Threats , Digital Communication , Cryptographic Protocols , Cyber Attacks , Data Protection
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