TY - JOUR
AU - Ollivier, Harold
AB - Abstract: With the recent availability of cloud quantum computing services, the question of the verifiability of quantum computations delegated by a weak quantum client to a powerful quantum server is becoming of practical interest. Over the last two decades, Verifiable Blind Quantum Computing (VBQC) has emerged as one of the key approaches to address this challenge. While many protocols have been proposed in recent years, each optimising one aspect of such schemes, a systematic study of required building blocks to achieve collectively the desired properties has been missing. We present a framework that encompasses all known VBQC protocols and present sufficient conditions to obtain composable security and noise robustness properties. We do this by providing a unified security proof within the Abstract Cryptography formalism that can be used for existing protocols as well as new ones that could be derived using the framework. While we choose Measurement-Based Quantum Computing (MBQC) as the working model for the presentation of our results, one could expand the domain of applicability of our framework via direct known translation between the circuit model and MBQC. On a theoretical note, we uncover fundamental relations between verification and error detection and correction, a folklore belief in the field that has never been mathematically proven: (i) verification can be reduced to the task of error detection, and (ii) encoding of the target computation into an error-correcting code is necessary for exponential soundness. These simple yet fundamental facts set the design principles for further development towards practical VBQC protocols. Indeed, as a direct application we demonstrate how the framework can systematize the search for new verification techniques. We find completely new schemes that allow more efficient robust verification of BQP computations than current state of the art.
TI - A Framework for Verifiable Blind Quantum Computation
JF - Quantum Physics
DA - 2022-06-01
UR - https://www.deepdyve.com/lp/arxiv-cornell-university/a-framework-for-verifiable-blind-quantum-computation-LaGXmjwWNe
VL - 2022
IS - 2206
DP - DeepDyve
ER -