完全连接的神经网络

IF 0.7 Q2 MATHEMATICS
W. Zhang, Zhi Han, Xi’ai Chen, Baicheng Liu, Huidi Jia, Yandong Tang
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引用次数: 0

摘要

本文将核方法应用于深度卷积神经网络(DCNN),以提高其非线性能力。DCNNs在许多计算机视觉任务中取得了显著的进步。对于一个图像分类任务来说,当网络的深度和宽度足够且合适时,准确率就会趋于饱和。即使增加深度和宽度,饱和度精度也不会提高。我们发现提高DCNNs的非线性能力可以突破饱和精度。在DCNN中,前一层更倾向于提取特征,后一层更倾向于对特征进行分类。因此,我们在最后一个全连通层采用核方法将特征隐式映射到高维空间,以提高网络的非线性能力,使网络具有更好的线性可分性。此外,我们将网络命名为全连接神经网络(具有核方法的全连接神经网络)。实验结果表明,与基线网络相比,全连接神经网络具有更高的分类精度和更快的收敛速度。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Fully Kernected Neural Networks
In this paper, we apply kernel methods to deep convolutional neural network (DCNN) to improve its nonlinear ability. DCNNs have achieved significant improvement in many computer vision tasks. For an image classification task, the accuracy comes to saturation when the depth and width of network are enough and appropriate. The saturation accuracy will not rise even by increasing the depth and width. We find that improving nonlinear ability of DCNNs can break through the saturation accuracy. In a DCNN, the former layer is more inclined to extract features and the latter layer is more inclined to classify features. Therefore, we apply kernel methods at the last fully connected layer to implicitly map features to a higher-dimensional space to improve nonlinear ability so that the network achieves better linear separability. Also, we name the network as fully kernected neural networks (fully connected neural networks with kernel methods). Our experiment result shows that fully kernected neural networks achieve higher classification accuracy and faster convergence rate than baseline networks.
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