Related papers: Increasing the Accuracy of a Neural Network Using Frequency Selective Mesh-to-Grid Resampling

Increasing the Accuracy of a Neural Network Using Frequency Selective Mesh-to-Grid Resampling

URL: http://arxiv.org/abs/2209.14431v1
Date: Wed, 28 Sep 2022 21:34:47 GMT
Title: Increasing the Accuracy of a Neural Network Using Frequency Selective Mesh-to-Grid Resampling
Authors: Andreas Spruck, Viktoria Heimann, Andr\'e Kaup
Abstract summary: We propose the use of keypoint frequency selective mesh-to-grid resampling (FSMR) for the processing of input data for neural networks. We show that depending on the network architecture and classification task the application of FSMR during training aids learning process. The classification accuracy can be increased by up to 4.31 percentage points for ResNet50 and the Oxflower17 dataset.
Score: 4.211128681972148
License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
Abstract: Neural networks are widely used for almost any task of recognizing image content. Even though much effort has been put into investigating efficient network architectures, optimizers, and training strategies, the influence of image interpolation on the performance of neural networks is not well studied. Furthermore, research has shown that neural networks are often sensitive to minor changes in the input image leading to drastic drops of their performance. Therefore, we propose the use of keypoint agnostic frequency selective mesh-to-grid resampling (FSMR) for the processing of input data for neural networks in this paper. This model-based interpolation method already showed that it is capable of outperforming common interpolation methods in terms of PSNR. Using an extensive experimental evaluation we show that depending on the network architecture and classification task the application of FSMR during training aids the learning process. Furthermore, we show that the usage of FSMR in the application phase is beneficial. The classification accuracy can be increased by up to 4.31 percentage points for ResNet50 and the Oxflower17 dataset.

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