Conceptos Básicos
The authors construct a succinct classical argument system for QMA, the quantum analogue of NP, from generic and standard cryptographic assumptions such as collapsing hash functions and a mild version of quantum homomorphic encryption. This avoids the need for the stronger assumption of post-quantum indistinguishability obfuscation required in prior work.
Resumen
The authors present a new approach to constructing succinct classical arguments for QMA problems, building on prior work on quantum verification and the compilation of quantum nonlocal games into cryptographic argument systems.
Key highlights:
- The authors avoid the use of post-quantum indistinguishability obfuscation, which was required in previous work, by instead relying on weaker cryptographic primitives such as collapsing hash functions and a mild version of quantum homomorphic encryption.
- They start with a question-succinct two-prover protocol for QMA and then compile it into a succinct single-prover argument system using the KLVY transformation.
- The analysis of the compiled protocol involves new techniques from approximate representation theory, including a version of the Gowers-Hatami theorem that supports non-uniform distributions.
- The authors also develop a succinct version of the Pauli braiding test, building on the work of de la Salle, and show how to analyze it in the compiled setting.
- The final protocol achieves constant completeness-soundness gap and polylogarithmic communication complexity, all from standard cryptographic assumptions.