International Association for Cryptologic Research

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On black-box separations of quantum digital signatures from pseudorandom states

Authors:
Andrea Coladangelo , University of Washington
Saachi Mutreja , Columbia University
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Conference: TCC 2024
Abstract: It is well-known that digital signatures can be constructed from one-way functions in a black-box way. While one-way functions are essentially the minimal assumption in classical cryptography, this is not the case in the quantum setting. A variety of qualitatively weaker and inherently quantum assumptions (e.g. EFI pairs, one-way state generators, and pseudorandom states) are known to be sufficient for non-trivial quantum cryptography. While it is known that commitments, zero-knowledge proofs, and even multiparty computation can be constructed from these assumptions, it has remained an open question whether the same is true for quantum digital signatures schemes (QDS). In this work, we show that there does not exist a black-box construction of a QDS scheme with classical signatures from pseudorandom states with linear, or greater, output length. Our result complements that of Morimae and Yamakawa (2022), who described a one-time secure QDS scheme with classical signatures, but left open the question of constructing a standard multi-time secure one.
BibTeX
@inproceedings{tcc-2024-34781,
  title={On black-box separations of quantum digital signatures from pseudorandom states},
  publisher={Springer-Verlag},
  author={Andrea Coladangelo and Saachi Mutreja},
  year=2024
}