An Interpretable Quantum Adjoint Convolutional Layer for Image Classification.

IF 9.4 1区计算机科学 Q1 AUTOMATION & CONTROL SYSTEMS

IEEE Transactions on Cybernetics Pub Date : 2025-05-22 DOI:10.1109/tcyb.2025.3567090

Shi Wang,Mengyi Wang,Ren-Xin Zhao,Licheng Liu,Yaonan Wang

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引用次数: 0

Abstract

The interpretability of quantum machine learning (QML) refers to the capability to provide clear and understandable explanations for the predictions and decision-making processes of QML models. However, most quantum convolutional layers (QCLs) utilize closed-box structures that are inherently devoid of interpretability, leading to the opacity of principles and the suboptimal mapping of classical data. This significantly undermines the reliability of QML models. In addition, most of the current QML interpretability focuses on post hoc interpretability seriously neglecting the importance of exploring intrinsic causes. To tackle these challenges, we introduce the quantum adjoint convolution operation (QACO). It is an intrinsic interpretability scheme based on quantum evolution, as its quantum mapping precisely corresponds to the position and pixel values of the image and its principle is equivalent to the Frobenius inner product (FIP). Furthermore, we extend the QACO concept into the quantum adjoint convolutional layer (QACL) by integrating the quantum phase estimation (QPE) algorithm, enabling the parallel computation of all FIPs. Experimental results on PennyLane and TensorFlow platforms demonstrate that our method achieves a 6.3%, 3.4%, and 2.9% higher average test accuracy on Fashion MNIST, MNIST, and DermaMNIST datasets compared to classical and uninterpretable quantum counterparts, respectively, while maintaining 73.3% noise-robust accuracy under Gaussian noise, showcasing its superior generalizability and resilience in practical scenarios.

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一种用于图像分类的可解释量子伴随卷积层。

量子机器学习（QML）的可解释性是指为QML模型的预测和决策过程提供清晰易懂的解释的能力。然而，大多数量子卷积层（qcl）利用封闭的盒子结构，固有地缺乏可解释性，导致原理的不透明性和经典数据的次优映射。这极大地破坏了QML模型的可靠性。此外，目前大多数QML可解释性研究都集中在事后可解释性上，严重忽视了探究内在原因的重要性。为了解决这些问题，我们引入了量子伴随卷积运算（QACO）。它是一种基于量子进化的内在可解释性方案，其量子映射精确对应于图像的位置和像素值，其原理等效于Frobenius内积（FIP）。此外，我们通过集成量子相位估计（QPE）算法，将QACO概念扩展到量子伴随卷积层（QACL），实现了所有FIPs的并行计算。在PennyLane和TensorFlow平台上的实验结果表明，我们的方法在Fashion MNIST、MNIST和DermaMNIST数据集上的平均测试精度分别比经典和不可解释的量子数据集高6.3%、3.4%和2.9%，同时在高斯噪声下保持73.3%的噪声鲁棒性精度，显示了其在实际场景中的优越泛化性和弹性。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

IEEE Transactions on Cybernetics COMPUTER SCIENCE, ARTIFICIAL INTELLIGENCE-COMPUTER SCIENCE, CYBERNETICS

CiteScore

25.40

自引率

11.00%

发文量

1869

期刊介绍： The scope of the IEEE Transactions on Cybernetics includes computational approaches to the field of cybernetics. Specifically, the transactions welcomes papers on communication and control across machines or machine, human, and organizations. The scope includes such areas as computational intelligence, computer vision, neural networks, genetic algorithms, machine learning, fuzzy systems, cognitive systems, decision making, and robotics, to the extent that they contribute to the theme of cybernetics or demonstrate an application of cybernetics principles.