Quantum convolutional neural network for classical data classification
TL;DR: In this paper , the authors proposed a quantum neural network model inspired by CNN that only uses two-qubit interactions throughout the entire algorithm, which achieved excellent classification accuracy despite having a small number of free parameters.
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Abstract: With the rapid advance of quantum machine learning, several proposals for the quantum-analogue of convolutional neural network (CNN) have emerged. In this work, we benchmark fully parameterized quantum convolutional neural networks (QCNNs) for classical data classification. In particular, we propose a quantum neural network model inspired by CNN that only uses two-qubit interactions throughout the entire algorithm. We investigate the performance of various QCNN models differentiated by structures of parameterized quantum circuits, quantum data encoding methods, classical data pre-processing methods, cost functions and optimizers on MNIST and Fashion MNIST datasets. In most instances, QCNN achieved excellent classification accuracy despite having a small number of free parameters. The QCNN models performed noticeably better than CNN models under the similar training conditions. Since the QCNN algorithm presented in this work utilizes fully parameterized and shallow-depth quantum circuits, it is suitable for Noisy Intermediate-Scale Quantum (NISQ) devices.
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Citations
Multiclass classification using quantum convolutional neural networks with hybrid quantum-classical learning
TL;DR: A quantum machine learning approach based on quantum convolutional neural networks for solvingMulticlass classification, a common task in computer vision, where one needs to categorize an image into three or more classes is proposed.
Compact quantum kernel-based binary classifier
TL;DR: This work presents the simplest quantum circuit for constructing a kernel-based binary classifier by generalizing the interference circuit to encode data labels in the relative phases of the quantum state and introducing compact amplitude encoding, which encodes two training data vectors into one quantum register.
Variational quantum one-class classifier
Gunhee Park,Joonsuk Huh,Daniel K. Park +2 more
- 06 Oct 2022
TL;DR: The algorithm is suitable for noisy intermediate-scale quantum computing because the VQOCC trains a fully-parameterized quantum autoencoder with a normal dataset and does not require decoding, and the number of model parameters grows only logarithmically with the data size.
Artificial intelligence (AI) for quantum and quantum for AI
Yingzhao Zhu,Kefeng Yu +1 more
TL;DR: A comprehensive overview on the reciprocal relationship between AI and quantum technology is presented, emphasizing the utility of AI in the field of quantum technology, and the potential of quantum technology to catalyze the evolution of AI.
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QSurfNet: a hybrid quantum convolutional neural network for surface defect recognition
Shraddha Mishra,Chi-Yi Tsai +1 more
TL;DR: QSurfNet is novel in terms of the algorithm design methodology that can turn any classical CNN algorithm into state-of-the-art QCNN, and contributes to the practical feasibility of developing novel convolutional architecture designs of hybrid quantum–classical algorithms.
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