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Main Authors: Keshava, Rakesh, Pandurangan, Sathish Kuppan, Sakthivanitha, M., Parmsivan, Sankaranainar, Sunkara, Goutham, Maruthi, R.
Format: Preprint
Published: 2026
Subjects:
Online Access:https://arxiv.org/abs/2601.06219
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author Keshava, Rakesh
Pandurangan, Sathish Kuppan
Sakthivanitha, M.
Parmsivan, Sankaranainar
Sunkara, Goutham
Maruthi, R.
author_facet Keshava, Rakesh
Pandurangan, Sathish Kuppan
Sakthivanitha, M.
Parmsivan, Sankaranainar
Sunkara, Goutham
Maruthi, R.
contents The rise in frequency and complexity of malware attacks are viewed as a major threat to modern digital infrastructure, which means that traditional signature-based detection methods are becoming less effective. As cyber threats continue to evolve, there is a growing need for intelligent systems to accurately and proactively identify and prevent malware infections. This study presents a new hybrid context-aware malware detection framework(HCAMDF) based on artificial intelligence (AI), which combines static file analysis, dynamic behavioural analysis, and contextual metadata to provide more accurate and timely detection. HCADMF has a multi-layer architecture, which consists of lightweight static classifiers such as Long Short Term Memory (LSTM) for real-time behavioral analysis, and an ensemble risk scoring through the integration of multiple layers of prediction. Experimental evaluations of the new/methodology with benchmark datasets, EMBER and CIC-MalMem2022, showed that the new approach provides superior performances with an accuracy of 97.3%, only a 1.5% false positive rate and minimal detection delay compared to several existing machine learning(ML) and deep learning(DL) established methods in the same fields. The results show strong evidence that hybrid AI can detect both existing and novel malware variants, and lay the foundation on intelligent security systems that can enable real-time detection and adapt to a rapidly evolving threat landscape.
format Preprint
id arxiv_https___arxiv_org_abs_2601_06219
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle AI-Powered Algorithms for the Prevention and Detection of Computer Malware Infections
Keshava, Rakesh
Pandurangan, Sathish Kuppan
Sakthivanitha, M.
Parmsivan, Sankaranainar
Sunkara, Goutham
Maruthi, R.
Cryptography and Security
Artificial Intelligence
The rise in frequency and complexity of malware attacks are viewed as a major threat to modern digital infrastructure, which means that traditional signature-based detection methods are becoming less effective. As cyber threats continue to evolve, there is a growing need for intelligent systems to accurately and proactively identify and prevent malware infections. This study presents a new hybrid context-aware malware detection framework(HCAMDF) based on artificial intelligence (AI), which combines static file analysis, dynamic behavioural analysis, and contextual metadata to provide more accurate and timely detection. HCADMF has a multi-layer architecture, which consists of lightweight static classifiers such as Long Short Term Memory (LSTM) for real-time behavioral analysis, and an ensemble risk scoring through the integration of multiple layers of prediction. Experimental evaluations of the new/methodology with benchmark datasets, EMBER and CIC-MalMem2022, showed that the new approach provides superior performances with an accuracy of 97.3%, only a 1.5% false positive rate and minimal detection delay compared to several existing machine learning(ML) and deep learning(DL) established methods in the same fields. The results show strong evidence that hybrid AI can detect both existing and novel malware variants, and lay the foundation on intelligent security systems that can enable real-time detection and adapt to a rapidly evolving threat landscape.
title AI-Powered Algorithms for the Prevention and Detection of Computer Malware Infections
topic Cryptography and Security
Artificial Intelligence
url https://arxiv.org/abs/2601.06219