Preserving individual privacy in ubiquitous e-commerce environments: a utility preserving approach for user-based privacy control

Neera, Jeyamohan (2022) Preserving individual privacy in ubiquitous e-commerce environments: a utility preserving approach for user-based privacy control. Doctoral thesis, Northumbria University.

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Abstract

Applications such as e-commerce, smart home appliances, and healthcare systems, amongst other
things, have become part and parcel of our daily lives. The data aggregated through these applications combined with state-of-the-art machine learning approaches have even increased the widespread uptake of these applications. However, such data aggregation and analytical practices have raised privacy concerns among users. Privacy-preserving machine learning models mitigate these concerns through private data aggregation and analytical techniques.

The first objective of this thesis is to design a privacy preserving data aggregation and analytical approach for recommendation systems. Recommendation systems rely heavily on behavioural and preferential data of a user to produce accurate recommendations. Aggregation of such data can reveal sensitive information about users to the Third-Party Service Providers (TPSPs). We start with designing a recommendation system that uses Local Differential Privacy (LDP) based input data perturbation mechanism to perturb users’ ratings locally before sending it to the TPSP. Hence, the TPSP aggregates only the perturbed ratings and has no access to original ratings. This approach protects a user’s privacy from TPSPs who aggregate ratings to infer any sensitive information. Next, we propose an LDP-based hybrid recommendation framework to protect users’ privacy from TPSPs who aggregate both ratings and reviews. We propose to perturb user ratings and pre-process user reviews at the user-side before sending them to the TPSP. Such an approach ensures that the TPSP cannot aggregate the original ratings or reviews from the users. However, these approaches still do not protect a user’s privacy from TPSPs who collect implicit feedback to predict a user’s preferences. Hence, we design an LDP-based federated matrix factorization for implicit feedback. We motivate the idea of stochastic gradient perturbation using the Bounded Laplace (BLP) mechanism to ensure strong privacy protection for users. The second objective of this thesis is to design a privacy preserving untraceable TPSP-based payment protocol. A TPSP based payment system does not protect a customer’s privacy in the face of an untrustworthy TPSP. Customers cannot make transactions anonymously as the TPSP collects detailed transaction-related information. TPSP uses this information to create a comprehensive behaviour profile of each customer, based on which TPSP can deduce sensitive information about a customer’s lifestyle. Hence we propose an untraceable payment system in this thesis to tackle this problem.

Item Type: Thesis (Doctoral)
Uncontrolled Keywords: differential privacy, third party based mobile payment, federated learning, cryptographic primitives, bounded Laplace mechanism
Subjects: G400 Computer Science
Department: Faculties > Engineering and Environment > Computer and Information Sciences
University Services > Graduate School > Doctor of Philosophy
Depositing User: John Coen
Date Deposited: 09 Nov 2022 09:59
Last Modified: 09 Nov 2022 10:00
URI: https://nrl.northumbria.ac.uk/id/eprint/50583

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