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Autore principale: Papa, Francis P.
Natura: Preprint
Pubblicazione: 2025
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Accesso online:https://arxiv.org/abs/2506.03318
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author Papa, Francis P.
author_facet Papa, Francis P.
contents Specific quantum algorithms exist to-in theory-break elliptic curve cryptographic protocols. Implementing these algorithms requires designing quantum circuits that perform elliptic curve arithmetic. To accurately judge a cryptographic protocol's resistance against future quantum computers, researchers figure out minimal resource-count circuits for performing these operations while still being correct. To assure the correctness of a circuit, it is integral to restore all ancilla qubits used to their original states. Failure to do so could result in decoherence of the computation's final result. Through rigorous classical simulation and unit testing, I surfaced four inconsistencies in the state-of-the-art quantum circuit for elliptic curve point addition where the circuit diagram states the qubits are returned in the original ($|0\rangle$) state, but the intermediate values are not uncomputed. I provide fixes to the circuit without increasing the leading-order gate cost.
format Preprint
id arxiv_https___arxiv_org_abs_2506_03318
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Validation of Quantum Elliptic Curve Point Addition Circuits
Papa, Francis P.
Quantum Physics
Specific quantum algorithms exist to-in theory-break elliptic curve cryptographic protocols. Implementing these algorithms requires designing quantum circuits that perform elliptic curve arithmetic. To accurately judge a cryptographic protocol's resistance against future quantum computers, researchers figure out minimal resource-count circuits for performing these operations while still being correct. To assure the correctness of a circuit, it is integral to restore all ancilla qubits used to their original states. Failure to do so could result in decoherence of the computation's final result. Through rigorous classical simulation and unit testing, I surfaced four inconsistencies in the state-of-the-art quantum circuit for elliptic curve point addition where the circuit diagram states the qubits are returned in the original ($|0\rangle$) state, but the intermediate values are not uncomputed. I provide fixes to the circuit without increasing the leading-order gate cost.
title Validation of Quantum Elliptic Curve Point Addition Circuits
topic Quantum Physics
url https://arxiv.org/abs/2506.03318