Development of a platform that improves user experience and content delivery

In today’s digital landscape, secure and accessible communication is challenged by unstable network connectivity, and privacy concerns. This thesis introduces a robust platform designed primarily for Android devices but extendable to other platforms. It leverages advanced technologies to ensure improved content delivery, secure file storage, and resilient data transfer. At its core, the solution employs a modular architecture consisting of an Android client, and a backend system. This design not only enhances maintainability and scalability but also uses strong encryption methods and a built-in caching system. A distinguishing feature of the platform is its privacy-first approach. By placing privacy at the very heart of its design philosophy, the system ensures that every interaction from core data handling routines to peripheral utility functions is governed by rigorous confidentiality standards. Ultimately, the platform’s unwavering commitment to privacy-first principles not only fosters user trust but also establishes a resilient foundation upon which all other features are built. A defining aspect of the platform is its focus on speeding up content delivery so that users can get the information they want right away. This emphasis on quick access makes the service free and easy to use for everyone. At the same time, it helps the servers work more efficiently when sending out content. As a result, users enjoy fast and reliable access, and the servers handle requests more smoothly without running into overloads. Together, these outcomes create an experience that feels both immediate and stable from start to finish. Manual end-to-end testing across multiple network providers, different cities, device models, and file types has demonstrated a 100% success rate in file transfers. These tests validate that combination of caching, encryption, and an optimized download strategy used in the platform reliably maintain data integrity and security in real world conditions.