SWAP-less Implementation of Quantum Algorithms
Abstract
We present a formalism based on tracking the flow of parity quantum information to implement algorithms on devices with limited connectivity without qubit overhead, SWAP operations or shuttling. Instead, we leverage the fact that entangling gates not only manipulate quantum states but can also be exploited to transport quantum information. We demonstrate the effectiveness of this method by applying it to the quantum Fourier transform (QFT) and the Quantum Approximate Optimization Algorithm (QAOA) with qubits. This improves upon all state-of-the-art implementations of the QFT on a linear nearest-neighbor architecture, resulting in a total circuit depth of and requiring CNOT gates. For the QAOA, our method outperforms SWAP networks, which are currently the most efficient implementation of the QAOA on a linear architecture. We further demonstrate the potential to balance qubit count against circuit depth by implementing the QAOA on twice the number of qubits using bi-linear connectivity, which approximately halves the circuit depth.
Keywords
Cite
@article{arxiv.2408.10907,
title = {SWAP-less Implementation of Quantum Algorithms},
author = {Berend Klaver and Stefan Rombouts and Michael Fellner and Anette Messinger and Kilian Ender and Katharina Ludwig and Wolfgang Lechner},
journal= {arXiv preprint arXiv:2408.10907},
year = {2026}
}
Comments
10 pages, 5 figures