Related papers: Quantum Anomaly Detection with a Spin Processor in Diamond

Quantum Anomaly Detection with a Spin Processor in Diamond

URL: http://arxiv.org/abs/2201.10263v2
Date: Sun, 3 Mar 2024 03:30:37 GMT
Title: Quantum Anomaly Detection with a Spin Processor in Diamond
Authors: Zihua Chai, Ying Liu, Mengqi Wang, Yuhang Guo, Fazhan Shi, Zhaokai Li, Ya Wang, Jiangfeng Du
Abstract summary: We experimentally demonstrate the anomaly detection of quantum states encoding audio samples with a three-qubit quantum processor. By training the quantum machine with a few normal samples, the quantum machine can detect the anomaly samples with a minimum error rate of 15.4%.
Score: 10.0891240648429
License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
Abstract: In the processing of quantum computation, analyzing and learning the pattern of the quantum data are essential for many tasks. Quantum machine learning algorithms can not only deal with the quantum states generated in the preceding quantum procedures, but also the quantum registers encoding classical problems. In this work, we experimentally demonstrate the anomaly detection of quantum states encoding audio samples with a three-qubit quantum processor consisting of solid-state spins in diamond. By training the quantum machine with a few normal samples, the quantum machine can detect the anomaly samples with a minimum error rate of 15.4%. These results show the power of quantum anomaly detection in dealing with machine learning tasks and the potential to detect abnormal output of quantum devices.

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