A single-qubit position verification protocol that is secure against multi-qubit attacks
This addresses the challenge of verifying positions securely against quantum attacks, which is crucial for security in both online and real-world applications, representing a novel approach rather than an incremental improvement.
The authors tackled the problem of secure position verification in quantum-equipped communications by showing that a single qubit combined with classical communication can thwart quantum adversaries using entanglement, and that increasing classical bits combats more entanglement, with protocols being noise-robust and feasible with current technology.
The position of a device or agent is an important security credential in today's society, both online and in the real world. Unless in direct proximity, however, the secure verification of a position is impossible without further assumptions. This is true classically, but also in any future quantum-equipped communications infrastructure. We show in this work that minimal quantum resources, in the form of a single qubit, combined with classical communication are sufficient to thwart quantum adversaries that pretend to be at a specific position and have the ability to coordinate their action with entanglement. More precisely, we show that the adversaries using an increasing amount of entanglement can be combatted solely by increasing the number of classical bits used in the protocol. The presented protocols are noise-robust and within reach of current quantum technology.