Quantum ensemble learning with a programmable superconducting processor
Abstract
Quantum machine learning is among the most exciting potential applications of quantum computing. However, the vulnerability of quantum information to environmental noises and the consequent high cost for realizing fault tolerance has impeded the quantum models from learning complex datasets. Here, we introduce AdaBoost.Q, a quantum adaptation of the classical adaptive boosting (AdaBoost) algorithm designed to enhance learning capabilities of quantum classifiers. Based on the probabilistic nature of quantum measurement, the algorithm improves the prediction accuracy by refining the attention mechanism during the adaptive training and combination of quantum classifiers. We experimentally demonstrate the versatility of our approach on a programmable superconducting processor, where we observe notable performance enhancements across various quantum machine learning models, including quantum neural networks and quantum convolutional neural networks. With AdaBoost.Q, we achieve an accuracy above 86% for a ten-class classification task over 10,000 test samples, and an accuracy of 100% for a quantum feature recognition task over 1,564 test samples. Our results demonstrate a foundational tool for advancing quantum machine learning towards practical applications, which has broad applicability to both the current noisy and the future fault-tolerant quantum devices.
Cite
@article{arxiv.2503.11047,
title = {Quantum ensemble learning with a programmable superconducting processor},
author = {Jiachen Chen and Yaozu Wu and Zhen Yang and Shibo Xu and Xuan Ye and Daili Li and Ke Wang and Chuanyu Zhang and Feitong Jin and Xuhao Zhu and Yu Gao and Ziqi Tan and Zhengyi Cui and Aosai Zhang and Ning Wang and Yiren Zou and Tingting Li and Fanhao Shen and Jiarun Zhong and Zehang Bao and Zitian Zhu and Zixuan Song and Jinfeng Deng and Hang Dong and Pengfei Zhang and Wei Zhang and Hekang Li and Qiujiang Guo and Zhen Wang and Ying Li and Xiaoting Wang and Chao Song and H. Wang},
journal= {arXiv preprint arXiv:2503.11047},
year = {2025}
}
Comments
9 pages, 4 figures