Gate Based Implementation of the Laplacian with BRGC Code for Universal Quantum Computers
Abstract
We study the gate-based implementation of the binary reflected Gray code (BRGC) and binary code of the unitary time evolution operator due to the Laplacian discretized on a lattice with periodic boundary conditions. We find that the resulting Trotter error is independent of system size for a fixed lattice spacing through the Baker-Campbell-Hausdorff formula. We then present our algorithm for building the BRGC quantum circuit. For an adiabatic evolution time with this circuit, and spectral norm error , we find the circuit cost (number of gates) and depth required are with auxiliary qubits for a system with lattice points per dimension and particle number ; an improvement over binary position encoding which requires an exponential number of -local operators. Further, under the reasonable assumption that bounds , with the kinetic energy and a non-trivial potential, the cost of QFT (Quantum Fourier Transform ) implementation of the Laplacian scales as with depth while BRGC scales as , giving an advantage to the BRGC implementation.
Cite
@article{arxiv.2207.11647,
title = {Gate Based Implementation of the Laplacian with BRGC Code for Universal Quantum Computers},
author = {Ermal Rrapaj and Kenneth S. McElvain and Chia Cheng Chang and Yantao Wu and André Walker-Loud},
journal= {arXiv preprint arXiv:2207.11647},
year = {2022}
}