Quantum Period Finding is Compression Robust

Authors

  • Alexander May Faculty of Computer Science Ruhr University Bochum, Bochum, Germany
  • Lars Schlieper Faculty of Computer Science Ruhr University Bochum, Bochum, Germany

DOI:

https://doi.org/10.46586/tosc.v2022.i1.183-211

Keywords:

Quantum period finding, Fourier transform, Simon, Shor, cryptographic applications

Abstract

We study quantum period finding algorithms such as Simon and Shor (and its variant Ekerå-Håstad). For a periodic function f these algorithms produce – via some quantum embedding of f – a quantum superposition ∑x |x〉 |f(x)〉, which requires a certain amount of output qubits that represent |f(x)〉. We show that one can lower this amount to a single output qubit by hashing f down to a single bit in an oracle setting.
Namely, we replace the embedding of f in quantum period finding circuits by oracle access to several embeddings of hashed versions of f. We show that on expectation this modification only doubles the required amount of quantum measurements, while significantly reducing the total number of qubits. For example, for Simon’s algorithm that finds periods in f : Fn2 → Fn2 our hashing technique reduces the required output qubits from n down to 1, and therefore the total amount of qubits from 2n to n + 1. We also show that Simon’s algorithm admits real world applications with only n + 1 qubits by giving a concrete realization of a hashed version of the cryptographic Even-Mansour construction. Moreover, for a variant of Simon’s algorithm on Even-Mansour that requires only classical queries to Even-Mansour we save a factor of (roughly) 4 in the qubits.
Our oracle-based hashed version of the Ekerå-Håstad algorithm for factoring n-bit RSA reduces the required qubits from (3/2 + o(1))n down to (1/2+ o(1))n.

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Published

2022-03-11

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Section

Articles

How to Cite

Quantum Period Finding is Compression Robust. (2022). IACR Transactions on Symmetric Cryptology, 2022(1), 183-211. https://doi.org/10.46586/tosc.v2022.i1.183-211