The Dilemma of Quantum Neural Networks

Yang Qian; Xinbiao Wang; Yuxuan Du; Xingyao Wu; Dacheng Tao

doi:10.1109/TNNLS.2022.3208313

The Dilemma of Quantum Neural Networks

Yang Qian, Xinbiao Wang, Yuxuan Du^*, Xingyao Wu, Dacheng Tao^*

^*Corresponding author for this work

Research output: Journal Publications and Reviews › RGC 21 - Publication in refereed journal › peer-review

20 Citations (Scopus)

Abstract

The core of quantum machine learning is to devise quantum models with good trainability and low generalization error bounds than their classical counterparts to ensure better reliability and interpretability. Recent studies confirmed that quantum neural networks (QNNs) have the ability to achieve this goal on specific datasets. In this regard, it is of great importance to understand whether these advantages are still preserved on real-world tasks. Through systematic numerical experiments, we empirically observe that current QNNs fail to provide any benefit over classical learning models. Concretely, our results deliver two key messages. First, QNNs suffer from the severely limited effective model capacity, which incurs poor generalization on real-world datasets. Second, the trainability of QNNs is insensitive to regularization techniques, which sharply contrasts with the classical scenario. These empirical results force us to rethink the role of current QNNs and to design novel protocols for solving real-world problems with quantum advantages. © 2012 IEEE.

Original language	English
Pages (from-to)	5603-5615
Journal	IEEE Transactions on Neural Networks and Learning Systems
Volume	35
Issue number	4
Online published	3 Oct 2022
DOIs	https://doi.org/10.1109/TNNLS.2022.3208313
Publication status	Published - Apr 2024
Externally published	Yes

Funding

The work of Yang Qian was supported by the Faculty of Engineering Research Scholarship provided by the Faculty of Engineering at the University of Sydney.

Research Keywords

Generalization
quantum neural network (QNN)
trainability
variational quantum algorithm

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title = "The Dilemma of Quantum Neural Networks",

abstract = "The core of quantum machine learning is to devise quantum models with good trainability and low generalization error bounds than their classical counterparts to ensure better reliability and interpretability. Recent studies confirmed that quantum neural networks (QNNs) have the ability to achieve this goal on specific datasets. In this regard, it is of great importance to understand whether these advantages are still preserved on real-world tasks. Through systematic numerical experiments, we empirically observe that current QNNs fail to provide any benefit over classical learning models. Concretely, our results deliver two key messages. First, QNNs suffer from the severely limited effective model capacity, which incurs poor generalization on real-world datasets. Second, the trainability of QNNs is insensitive to regularization techniques, which sharply contrasts with the classical scenario. These empirical results force us to rethink the role of current QNNs and to design novel protocols for solving real-world problems with quantum advantages. {\textcopyright} 2012 IEEE.",

keywords = "Generalization, quantum neural network (QNN), trainability, variational quantum algorithm",

author = "Yang Qian and Xinbiao Wang and Yuxuan Du and Xingyao Wu and Dacheng Tao",

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AU - Qian, Yang

AU - Wang, Xinbiao

AU - Du, Yuxuan

AU - Wu, Xingyao

AU - Tao, Dacheng

PY - 2024/4

Y1 - 2024/4

N2 - The core of quantum machine learning is to devise quantum models with good trainability and low generalization error bounds than their classical counterparts to ensure better reliability and interpretability. Recent studies confirmed that quantum neural networks (QNNs) have the ability to achieve this goal on specific datasets. In this regard, it is of great importance to understand whether these advantages are still preserved on real-world tasks. Through systematic numerical experiments, we empirically observe that current QNNs fail to provide any benefit over classical learning models. Concretely, our results deliver two key messages. First, QNNs suffer from the severely limited effective model capacity, which incurs poor generalization on real-world datasets. Second, the trainability of QNNs is insensitive to regularization techniques, which sharply contrasts with the classical scenario. These empirical results force us to rethink the role of current QNNs and to design novel protocols for solving real-world problems with quantum advantages. © 2012 IEEE.

AB - The core of quantum machine learning is to devise quantum models with good trainability and low generalization error bounds than their classical counterparts to ensure better reliability and interpretability. Recent studies confirmed that quantum neural networks (QNNs) have the ability to achieve this goal on specific datasets. In this regard, it is of great importance to understand whether these advantages are still preserved on real-world tasks. Through systematic numerical experiments, we empirically observe that current QNNs fail to provide any benefit over classical learning models. Concretely, our results deliver two key messages. First, QNNs suffer from the severely limited effective model capacity, which incurs poor generalization on real-world datasets. Second, the trainability of QNNs is insensitive to regularization techniques, which sharply contrasts with the classical scenario. These empirical results force us to rethink the role of current QNNs and to design novel protocols for solving real-world problems with quantum advantages. © 2012 IEEE.

KW - Generalization

KW - quantum neural network (QNN)

KW - trainability

KW - variational quantum algorithm

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JO - IEEE Transactions on Neural Networks and Learning Systems

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The Dilemma of Quantum Neural Networks

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Research Keywords

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