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Towards Efficient Quantum Anomaly Detection: One-Class SVMs using Variable Subsampling and Randomized Measurements

Quantum Physics 2023-12-15 v1 Machine Learning

Abstract

Quantum computing, with its potential to enhance various machine learning tasks, allows significant advancements in kernel calculation and model precision. Utilizing the one-class Support Vector Machine alongside a quantum kernel, known for its classically challenging representational capacity, notable improvements in average precision compared to classical counterparts were observed in previous studies. Conventional calculations of these kernels, however, present a quadratic time complexity concerning data size, posing challenges in practical applications. To mitigate this, we explore two distinct approaches: utilizing randomized measurements to evaluate the quantum kernel and implementing the variable subsampling ensemble method, both targeting linear time complexity. Experimental results demonstrate a substantial reduction in training and inference times by up to 95\% and 25\% respectively, employing these methods. Although unstable, the average precision of randomized measurements discernibly surpasses that of the classical Radial Basis Function kernel, suggesting a promising direction for further research in scalable, efficient quantum computing applications in machine learning.

Keywords

Cite

@article{arxiv.2312.09174,
  title  = {Towards Efficient Quantum Anomaly Detection: One-Class SVMs using Variable Subsampling and Randomized Measurements},
  author = {Michael Kölle and Afrae Ahouzi and Pascal Debus and Robert Müller and Danielle Schuman and Claudia Linnhoff-Popien},
  journal= {arXiv preprint arXiv:2312.09174},
  year   = {2023}
}

Comments

Accepted at ICAART 2024

R2 v1 2026-06-28T13:51:22.277Z