A Novel Privacy Preservation Scheme by Matrix Factorized Deep Autoencoder
Автор: Pooja Choudhary, Kanwal Garg
Журнал: International Journal of Computer Network and Information Security @ijcnis
Статья в выпуске: 3 vol.16, 2024 года.
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Data transport entails substantial security to avoid unauthorized snooping as data mining yields important and quite often sensitive information that must be and can be secured using one of the myriad Data Privacy Preservation methods. This study aspires to provide new knowledge to the study of protecting personal information. The key contributions of the work are an imputation method for filling in missing data before learning item profiles and the optimization of the Deep Auto-encoded NMF with a customizable learning rate. We used Bayesian inference to assess imputation for data with 13%, 26%, and 52% missing at random. By correcting any inherent biases, the results of decomposition problems may be enhanced. As the statistical analysis tool, MAPE is used. The proposed approach is evaluated on the Wiki dataset and the traffic dataset, against state-of-the-art techniques including BATF, BGCP, BCPF, and modified PARAFAC, all of which use a Bayesian Gaussian tensor factorization. Using this approach, the MAPE index is decreased for data which avails privacy safeguards than its corresponding original forms.
Privacy Preservation, Matrix Factorization, Autoencoder, Deep Learning
Короткий адрес: https://sciup.org/15019286
IDR: 15019286 | DOI: 10.5815/ijcnis.2024.03.07
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