Explore Real Random’s collection of technical resources, research papers, and documentation designed to help businesses, developers, and researchers understand and implement true quantum-secure entropy. From foundational terminology in our Glossary, to peer-reviewed testing results, mobile SDK integration guides, and academic studies on physical entropy, these materials demonstrate how Real Random’s physics-based randomness achieves measurable security in the post-quantum era.
A concise reference of key terms related to entropy, randomness, and post-quantum cryptography. The glossary defines concepts that form the foundation of Real Random’s quantum-grade security design, helping readers understand how physics-based entropy contributes to stronger cryptographic systems.
Explore technical resources that explain how Real Random’s physics-based entropy can be integrated into mobile and enterprise systems designed for post-quantum resilience. These documents include developer SDK guidance and verified test results that demonstrate the consistency, strength, and independence of Real Random’s entropy output.
A developer guide detailing how to integrate Real Random’s physics-based entropy services into mobile applications. Includes API setup, authentication, and implementation examples for delivering verifiable randomness to strengthen cryptographic key generation on mobile devices.
Independent testing that validates the statistical quality and unpredictability of Real Random’s entropy output. Summarizes NIST, Dieharder, and Fourmilab evaluations, confirming consistent high-entropy performance across large-scale data samples.
Review academic and applied studies exploring the science and implementation of physical entropy in secure communications. These papers outline Real Random’s quantum-grade approach to randomness generation, its relevance to cryptographic key creation, and ongoing research into securing data against emerging quantum-era threats.
A technical overview of how physics-based entropy enhances mobile encryption. Explores challenges in conventional random number generation and presents Real Random’s quantum-grade approach to securing data transmissions in a post-quantum environment.
Academic research comparing Real Random’s physical entropy generation to traditional digital methods. Examines entropy measurement techniques and the implications of physics-based randomness for future cryptographic standards.
