Scientists Develop Fastest-Ever Quantum Random Number Generator
(PRNewswire) An international research team has developed a fast and affordable quantum random number generator. The device created by scientists from NUST MISIS, Russian Quantum Center, University of Oxford, Goldsmiths, University of London and Freie Universität Berlin produces randomness at a rate of 8.05 gigabits per second, which makes it the fastest random number generator of its kind. The study published in Physics Review X is a promising starting point for the development of commercial random number generators for cryptography and complex systems modeling.
Random number generation (RNG) is used in encryption with a multitude of applications, including cryptography, numerical simulation, gambling and game development. Random numbers are at the core of strong, unique encryption keys used to protect cryptographic operations from being breached. RNG can also enhance the performance of AI-powered systems.
Even though computer-generated numbers might seem random, true randomness is extremely hard to achieve. Random number generators implemented in software based algorithms produce random-looking yet deterministic sequences of numbers, which poses numerous information security vulnerabilities.
n search for true randomness scientists have turned to quantum mechanics. Since randomness is a fundamental property of quantum processes, quantum events can be harnessed to generate truly random numbers. In their experiments, the researchers used the inherently unpredictable behavior of photons to generate randomness. They created an optical generator with a built-in certification protocol to ensure the random nature of the number generation process.
To confirm that randomness generated by the device was reliable, the researchers performed another measurement to make sure that the light signal contains a sufficient number of photons. If the number of photons is insufficient, the number of possible unpredictable events will be too low for the obtained randomness to be confirmed true. If the photon input is too high, both detectors will hit their maximum value, resulting in the measurement being fully predictable