Performance of Practical Quantum Oblivious Key Distribution
Abstract
Motivated by the applications of secure multiparty computation as a privacy-protecting data analysis tool, and identifying oblivious transfer as one of its main practical enablers, we propose a practical realization of randomized quantum oblivious transfer. By using only symmetric cryptography primitives to implement commitments, we construct computationally-secure randomized oblivious transfer without the need for public-key cryptography or assumptions imposing limitations on the adversarial devices. We show that the protocol is secure under an indistinguishability-based notion of security and demonstrate an experimental implementation to test its real-world performance. Its security and performance are then compared to both quantum and classical alternatives, showing potential advantages over existing solutions based on the noisy storage model and public-key cryptography.
Cite
@article{arxiv.2501.03973,
title = {Performance of Practical Quantum Oblivious Key Distribution},
author = {Mariano Lemus and Peter Schiansky and Manuel Goulão and Mathieu Bozzio and David Elkouss and Nikola Paunković and Paulo Mateus and Philip Walther},
journal= {arXiv preprint arXiv:2501.03973},
year = {2025}
}
Comments
40 pages, 5 images