A hybrid machine learning model with self-improved optimization algorithm for trust and privacy preservation in cloud environment

A hybrid machine learning model with self-improved optimization algorithm for trust and privacy preservation in cloud environment

Abstract The rapid adoption of cloud-based data sharing is transforming collaboration across various sectors, yet ensuring trust and privacy in sensitive data remains a critical challenge. This paper presents a hybrid model aimed at enhancing data privacy and trust in cloud environments, specificall...

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Bibliographic Details
Main Authors: Himani Saini, Gopal Singh, Sandeep Dalal, Iyyappan Moorthi, Sultan Mesfer Aldossary, Nasratullah Nuristani, Arshad Hashmi
Format: Article
Language:English
Published: SpringerOpen 2024-11-01
Series:Journal of Cloud Computing: Advances, Systems and Applications
Subjects:
Time-aware modified best fit decreasing (T-MBFD)
Resource allocation
Privacy preservation
Trust generation
State-of-the-art algorithms
Online Access:https://doi.org/10.1186/s13677-024-00717-6
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Summary:Abstract The rapid adoption of cloud-based data sharing is transforming collaboration across various sectors, yet ensuring trust and privacy in sensitive data remains a critical challenge. This paper presents a hybrid model aimed at enhancing data privacy and trust in cloud environments, specifically addressing concerns in healthcare and finance. The model combines k-anonymity for user privacy, an optimized Firefly algorithm for trust generation, and a Time-aware Modified Best Fit Decreasing (T-MBFD) algorithm to improve resource allocation efficiency. Key contributions include a comprehensive methodology that encompasses dataset selection, preprocessing, model training, and evaluation across multiple datasets, including healthcare, financial, and pandemic-related data. Experimental results demonstrate that the hybrid model achieves a precision score of approximately 90% and an accuracy of around 93% in financial datasets, significantly outperforming existing methods in both privacy preservation and computational efficiency. These findings emphasize the model’s effectiveness in securely facilitating data-driven collaboration in highly regulated domains, thus paving the way for practical applications that uphold individual privacy and data integrity in cloud-based environments.
ISSN:2192-113X

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