English

Succinct Classical Verification of Quantum Computation

Quantum Physics 2022-07-01 v1 Cryptography and Security

Abstract

We construct a classically verifiable succinct interactive argument for quantum computation (BQP) with communication complexity and verifier runtime that are poly-logarithmic in the runtime of the BQP computation (and polynomial in the security parameter). Our protocol is secure assuming the post-quantum security of indistinguishability obfuscation (iO) and Learning with Errors (LWE). This is the first succinct argument for quantum computation in the plain model; prior work (Chia-Chung-Yamakawa, TCC '20) requires both a long common reference string and non-black-box use of a hash function modeled as a random oracle. At a technical level, we revisit the framework for constructing classically verifiable quantum computation (Mahadev, FOCS '18). We give a self-contained, modular proof of security for Mahadev's protocol, which we believe is of independent interest. Our proof readily generalizes to a setting in which the verifier's first message (which consists of many public keys) is compressed. Next, we formalize this notion of compressed public keys; we view the object as a generalization of constrained/programmable PRFs and instantiate it based on indistinguishability obfuscation. Finally, we compile the above protocol into a fully succinct argument using a (sufficiently composable) succinct argument of knowledge for NP. Using our framework, we achieve several additional results, including - Succinct arguments for QMA (given multiple copies of the witness), - Succinct non-interactive arguments for BQP (or QMA) in the quantum random oracle model, and - Succinct batch arguments for BQP (or QMA) assuming post-quantum LWE (without iO).

Keywords

Cite

@article{arxiv.2206.14929,
  title  = {Succinct Classical Verification of Quantum Computation},
  author = {James Bartusek and Yael Tauman Kalai and Alex Lombardi and Fermi Ma and Giulio Malavolta and Vinod Vaikuntanathan and Thomas Vidick and Lisa Yang},
  journal= {arXiv preprint arXiv:2206.14929},
  year   = {2022}
}

Comments

CRYPTO 2022

R2 v1 2026-06-24T12:08:58.039Z