Realizing Quantum Convolutional Neural Networks on a Superconducting Quantum Processor to Recognize Quantum Phases
Abstract
Quantum computing crucially relies on the ability to efficiently characterize the quantum states output by quantum hardware. Conventional methods which probe these states through direct measurements and classically computed correlations become computationally expensive when increasing the system size. Quantum neural networks tailored to recognize specific features of quantum states by combining unitary operations, measurements and feedforward promise to require fewer measurements and to tolerate errors. Here, we realize a quantum convolutional neural network (QCNN) on a 7-qubit superconducting quantum processor to identify symmetry-protected topological (SPT) phases of a spin model characterized by a non-zero string order parameter. We benchmark the performance of the QCNN based on approximate ground states of a family of cluster-Ising Hamiltonians which we prepare using a hardware-efficient, low-depth state preparation circuit. We find that, despite being composed of finite-fidelity gates itself, the QCNN recognizes the topological phase with higher fidelity than direct measurements of the string order parameter for the prepared states.
Cite
@article{arxiv.2109.05909,
title = {Realizing Quantum Convolutional Neural Networks on a Superconducting Quantum Processor to Recognize Quantum Phases},
author = {Johannes Herrmann and Sergi Masot Llima and Ants Remm and Petr Zapletal and Nathan A. McMahon and Colin Scarato and Francois Swiadek and Christian Kraglund Andersen and Christoph Hellings and Sebastian Krinner and Nathan Lacroix and Stefania Lazar and Michael Kerschbaum and Dante Colao Zanuz and Graham J. Norris and Michael J. Hartmann and Andreas Wallraff and Christopher Eichler},
journal= {arXiv preprint arXiv:2109.05909},
year = {2022}
}