User-Controlled Privacy-Preserving User Profile Data Sharing based on Blockchain

TL;DR

This paper proposes a decentralized, blockchain-based architecture for user-controlled privacy-preserving data sharing in the travel domain, enabling users to decide what personal data to share while maintaining privacy and system efficiency.

Contribution

It introduces a novel blockchain framework using MultiChain for user-controlled data sharing, applicable across multiple domains, with performance evaluation on latency and memory usage.

Findings

Low latency in data sharing scenarios

Efficient memory consumption during operations

User control over data sharing is effectively implemented

Abstract

The tremendous technological advancement in the last few decades has brought many enterprises to collaborate in a better way while making intelligent decisions. The use of Information Technology tools in obtaining data of people's everyday life from various autonomous data sources allowing unrestricted access to user data has emerged as an important practical issue and has given rise to legal implications. Various innovative models for data sharing and management have privacy and centrality issues. To alleviate these limitations, we have incorporated blockchain in user modeling. In this paper, we constructed a decentralized data sharing architecture with MultiChain blockchain in the travel domain, which is also applicable to other similar domains including education, health, and sports. Businesses that operate in the tourism industries including travel and tour agencies, hotels and resorts, shopping malls are connected to the MultiChain and they share their user profile data via stream in the MultiChain. The paper presents the hotel booking service for an imaginary hotel as one of the enterprise nodes, which collects user profile data with proper validation and will allow users to decide which of their data to be shared thus ensuring user control over their data and the preservation of privacy. The data from the repository is converted into an open data format while sharing via stream in the blockchain so that other enterprise nodes, after receiving the data, can easily convert them and store into their own repositories. The paper presents an evaluation of the performance of the model by measuring the latency and memory consumption with three test scenarios that mostly affect the user experience. The node responded quickly in all of these cases.