Classical verification of quantum measurement for the computational basis and the XY -plane basis

Recent advances in quantum technologies raise the urgent need of verifying the correct functionality of a quantum device. Certifying the correctness of a quantum device in a fully classical manner is an important research branch. In this paper, we present a measurement protocol that allows a classical verifier to interact with an efficient quantum prover to verify the computational basis or the $XY$-plane basis measurement on a quantum state. With the help of two adaptive hardcore bit properties of a noisy trapdoor claw-free family, the security of measurement protocol is proved, which is under quantum hardness of the learning with error. The security characterizes the distance between the output distribution of measurement protocol and the distribution obtained by measuring certain quantum states in the designated basis, with or without the presence of honest behavior of the prover. Moreover, exploiting the measurement protocol, we present two device-noise-independent verification protocols of graph states and a classical verification protocol of delegated quantum computing whose soundness is 0.5757.