Quantum Period Finding is Compression Robust
Alexander May, Lars Schlieper

TL;DR
This paper introduces a hashing technique that reduces the quantum resources needed for period finding algorithms like Simon and Shor by lowering output qubits to a single bit, enabling more practical quantum computations.
Contribution
The authors propose a method to decrease the number of output qubits in quantum period finding algorithms using hashing, significantly reducing qubit requirements and enabling real-world applications.
Findings
Reduces output qubits from n to 1 in Simon's algorithm.
Halves qubit requirements in RSA factoring algorithms.
Decreases qubits in discrete logarithm applications by a linear factor.
Abstract
We study quantum period finding algorithms such as Simon and Shor (and its variants Eker{\aa}-H{\aa}stad and Mosca-Ekert). For a periodic function these algorithms produce -- via some quantum embedding of -- a quantum superposition , which requires a certain amount of output qubits that represent . We show that one can lower this amount to a single output qubit by hashing down to a single bit in an oracle setting. Namely, we replace the embedding of in quantum period finding circuits by oracle access to several embeddings of hashed versions of . 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 our hashing…
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Taxonomy
TopicsCryptography and Data Security · Coding theory and cryptography · Quantum Computing Algorithms and Architecture
