TY - GEN
T1 - A Quick Overview of Quantum Machine Learning
AU - Jiang, Jehn Ruey
N1 - Publisher Copyright:
© 2023 IEEE.
PY - 2023
Y1 - 2023
N2 - Quantum machine learning (QML), which integrates quantum computing and machine learning techniques, has attracted much research attention in recent years. A previous study proposed a four-class classification for QML techniques based on whether the data and computations are in quantum or classical forms. Based on the four-class classification, I introduced examples and applications for each class of QML techniques. Two of the four classes have more research results than the other two. They are the CC class, where classical data are processed by classical models with the quantum computing flavor, and the CQ class, where classical data are processed by quantum-based models. More research results related to the CC and CQ classes are presented in this article. The introduced techniques include quantum-inspired binary classifiers, quantum-inspired multi-class classifiers, quantum-inspired support vector machines, quantum-inspired linear regression, and quantum-inspired recommendation systems of the CC class. They also include quantum support vector machines, quantum neural networks, quantum convolutional neural networks, and quantum autoencoders of the CQ class. Finally, possible research directions are suggested for each class, especially for the CC and CQ classes. The suggested research directions encompass hybrid classical-quantum machine learning, quantum K-nearest neighbor, quantum clustering, quantum generative adversarial network, and quantum reinforcement learning techniques.
AB - Quantum machine learning (QML), which integrates quantum computing and machine learning techniques, has attracted much research attention in recent years. A previous study proposed a four-class classification for QML techniques based on whether the data and computations are in quantum or classical forms. Based on the four-class classification, I introduced examples and applications for each class of QML techniques. Two of the four classes have more research results than the other two. They are the CC class, where classical data are processed by classical models with the quantum computing flavor, and the CQ class, where classical data are processed by quantum-based models. More research results related to the CC and CQ classes are presented in this article. The introduced techniques include quantum-inspired binary classifiers, quantum-inspired multi-class classifiers, quantum-inspired support vector machines, quantum-inspired linear regression, and quantum-inspired recommendation systems of the CC class. They also include quantum support vector machines, quantum neural networks, quantum convolutional neural networks, and quantum autoencoders of the CQ class. Finally, possible research directions are suggested for each class, especially for the CC and CQ classes. The suggested research directions encompass hybrid classical-quantum machine learning, quantum K-nearest neighbor, quantum clustering, quantum generative adversarial network, and quantum reinforcement learning techniques.
KW - quantum autoencoder
KW - quantum convolutional neural network
KW - quantum machine learning
KW - quantum neural network
KW - quantum support vector machine
UR - http://www.scopus.com/inward/record.url?scp=85184102920&partnerID=8YFLogxK
U2 - 10.1109/ECICE59523.2023.10383149
DO - 10.1109/ECICE59523.2023.10383149
M3 - 會議論文篇章
AN - SCOPUS:85184102920
T3 - 2023 IEEE 5th Eurasia Conference on IOT, Communication and Engineering, ECICE 2023
SP - 301
EP - 304
BT - 2023 IEEE 5th Eurasia Conference on IOT, Communication and Engineering, ECICE 2023
A2 - Meen, Teen-Hang
PB - Institute of Electrical and Electronics Engineers Inc.
T2 - 5th IEEE Eurasia Conference on IOT, Communication and Engineering, ECICE 2023
Y2 - 27 October 2023 through 29 October 2023
ER -