Code-routing: a new attack on position verification
Abstract
The cryptographic task of position verification attempts to verify one party's location in spacetime by exploiting constraints on quantum information and relativistic causality. A popular verification scheme known as -routing involves requiring the prover to redirect a quantum system based on the value of a Boolean function . Cheating strategies for the -routing scheme require the prover use pre-shared entanglement, and security of the scheme rests on assumptions about how much entanglement a prover can manipulate. Here, we give a new cheating strategy in which the quantum system is encoded into a secret-sharing scheme, and the authorization structure of the secret-sharing scheme is exploited to direct the system appropriately. This strategy completes the -routing task using EPR pairs, where is the minimal size of a span program over the field computing . This shows we can efficiently attack -routing schemes whenever is in the complexity class , after allowing for local pre-processing. The best earlier construction achieved the class L, which is believed to be strictly inside of . We also show that the size of a quantum secret sharing scheme with indicator function upper bounds entanglement cost of -routing on the function .
Keywords
Cite
@article{arxiv.2202.07812,
title = {Code-routing: a new attack on position verification},
author = {Joy Cree and Alex May},
journal= {arXiv preprint arXiv:2202.07812},
year = {2023}
}
Comments
29 pages, v4 adds minor comments