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During most eukaryotic translation processes, the small 40S ribosome subunit scans an mRNA from its 5' end until it encounters the first start AUG codon. The large 60S ribosomal subunit then joins the smaller one to initiate protein synthesis. The location of the translation initiation is largely determined by the nucleotides near the start codon as there may be multiple translation initiation sites present on the mRNA.  Marilyn Kozak discovered that the sequence RCCAUGG (where R...
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LEDA-Layered Event-Based Malware Detection Architecture.

Radu Marian Portase1,2, Raluca Laura Portase1, Adrian Colesa1,2

  • 1Computer Science Department, Technical University of Cluj Napoca, 400114 Cluj Napoca, Romania.

Sensors (Basel, Switzerland)
|October 16, 2024
PubMed
Summary
This summary is machine-generated.

This study introduces LEDA, a real-time malware detection system. LEDA efficiently identifies malicious processes by learning relevant features, improving upon traditional methods for enhanced cybersecurity.

Keywords:
machine learningmalware detection architectureprocess behavior monitoringreal-time malware detection

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Area of Science:

  • Computer Science
  • Cybersecurity
  • Machine Learning

Background:

  • The proliferation of new malware strains demands advanced detection techniques.
  • Existing machine learning approaches often rely on static file analysis or comprehensive process logs, which can be inefficient or redundant for certain malware types like ransomware.
  • Real-time detection is crucial for mitigating rapidly evolving cyber threats.

Purpose of the Study:

  • To introduce LEDA, a novel malware detection architecture for real-time process behavior monitoring.
  • To develop a system that dynamically learns discriminative features and optimizes model evaluation for minimal user-perceived performance impact.
  • To address the limitations of traditional malware detection methods, particularly for malware that announces its presence, such as ransomware.

Main Methods:

  • LEDA employs a real-time process behavior monitoring approach.
  • The architecture dynamically identifies and learns the most relevant features for malware detection.
  • It optimally triggers model evaluations to balance detection accuracy and system performance.

Main Results:

  • LEDA demonstrated effectiveness in detecting Windows malware in real-time.
  • The system dynamically adapts to learn critical features, improving detection efficiency.
  • Evaluation using a year-long dataset of malware and legitimate applications provided insights into the model's temporal effectiveness.

Conclusions:

  • LEDA offers a promising real-time malware detection solution, outperforming traditional methods for specific threats.
  • Dynamic feature learning and optimized model evaluation are key to efficient and effective malware detection.
  • Further research should explore the long-term temporal decay of LEDA's effectiveness in diverse and evolving threat landscapes.