Typical Machine Learning Datasets as Low-Depth Quantum Circuits

TL;DR

This paper develops an efficient method for constructing low-depth quantum circuits to load classical image data into quantum states, enabling practical quantum machine learning applications on standard datasets.

Contribution

It introduces an algorithm for low-depth quantum data loading tailored for structured data like images, facilitating scalable quantum machine learning.

Findings

Quantum circuits for datasets like MNIST and CIFAR-10 are publicly available.

Quantum classifiers are systematically compared to classical CNNs.

Performance analysis of quantum models with nonlinear input functions.

Abstract

Quantum machine learning (QML) is an emerging field that investigates the capabilities of quantum computers for learning tasks. While QML models can theoretically offer advantages such as exponential speed-ups, challenges in data loading and the ability to scale to relevant problem sizes have prevented demonstrations of such advantages on practical problems. In particular, the encoding of arbitrary classical data into quantum states usually comes at a high computational cost, either in terms of qubits or gate count. However, real-world data typically exhibits some inherent structure (such as image data) which can be leveraged to load them with a much smaller cost on a quantum computer. This work further develops an efficient algorithm for finding low-depth quantum circuits to load classical image data as quantum states. To evaluate its effectiveness, we conduct systematic studies on the MNIST, Fashion-MNIST, CIFAR-10, and Imagenette datasets. The corresponding circuits for loading the full large-scale datasets are available publicly as PennyLane datasets and can be used by the community for their own benchmarks. We further analyze the performance of various quantum classifiers, such as quantum kernel methods, parameterized quantum circuits, and tensor-network classifiers, and we compare them to convolutional neural networks. In particular, we focus on the performance of the quantum classifiers as we introduce nonlinear functions of the input state, e.g., by letting the circuit parameters depend on the input state.