International Association for Cryptologic Research

International Association
for Cryptologic Research

CryptoDB

Semi-Quantum Copy-Protection and More

Authors:
Céline Chevalier , DIENS, École normale supérieure, PSL University, CNRS, INRIA, Paris, France; CRED, Université Panthéon-Assas Paris 2, Paris, France
Paul Hermouet , DIENS, École normale supérieure, PSL University, CNRS, INRIA, Paris, France; CRED, Université Panthéon-Assas Paris 2, Paris, France; Sorbonne Université, CNRS, LIP6
Quoc-Huy Vu , Sorbonne Université, CNRS, LIP6
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Presentation: Slides
Conference: TCC 2023
Abstract: Properties of quantum mechanics have enabled the emergence of quantum cryptographic protocols achieving important goals which are proven to be impossible classically. Unfortunately, this usually comes at the cost of needing quantum power from every party in the protocol, while arguably a more realistic scenario would be a network of classical clients, classically interacting with a quantum server. In this paper, we focus on copy-protection, which is a quantum primitive that allows a program to be evaluated, but not copied, and has shown interest especially due to its links to other unclonable cryptographic primitives. Our main contribution is to show how to dequantize quantum copy-protection schemes constructed from hidden coset states, by giving a construction for classically-instructed remote state preparation for coset states, which *preserves hardness properties of hidden coset states*. We then apply this dequantizer to obtain semi-quantum cryptographic protocols for copy-protection and tokenized signatures with strong unforgeability. In the process, we present the first secure copy-protection scheme for point functions in the plain model and a new direct product hardness property of coset states which immediately implies a strongly unforgeable tokenized signature scheme.
BibTeX
@inproceedings{tcc-2023-33462,
  title={Semi-Quantum Copy-Protection and More},
  publisher={Springer-Verlag},
  author={Céline Chevalier and Paul Hermouet and Quoc-Huy Vu},
  year=2023
}