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Bibliographic Details
Main Authors: Cammarasana, Simone, Patanè, Giuseppe
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2505.24527
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author Cammarasana, Simone
Patanè, Giuseppe
author_facet Cammarasana, Simone
Patanè, Giuseppe
contents The paper introduces the weighted convolution, a novel approach to the convolution for signals defined on regular grids (e.g., 2D images) through the application of an optimal density function to scale the contribution of neighbouring pixels based on their distance from the central pixel. This choice differs from the traditional uniform convolution, which treats all neighbouring pixels equally. Our weighted convolution can be applied to convolutional neural network problems to improve the approximation accuracy. Given a convolutional network, we define a framework to compute the optimal density function through a minimisation model. The framework separates the optimisation of the convolutional kernel weights (using stochastic gradient descent) from the optimisation of the density function (using DIRECT-L). Experimental results on a learning model for an image-to-image task (e.g., image denoising) show that the weighted convolution significantly reduces the loss (up to 53% improvement) and increases the test accuracy compared to standard convolution. While this method increases execution time by 11%, it is robust across several hyperparameters of the learning model. Future work will apply the weighted convolution to real-case 2D and 3D image convolutional learning problems.
format Preprint
id arxiv_https___arxiv_org_abs_2505_24527
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Optimal Density Functions for Weighted Convolution in Learning Models
Cammarasana, Simone
Patanè, Giuseppe
Computer Vision and Pattern Recognition
Machine Learning
42A85
The paper introduces the weighted convolution, a novel approach to the convolution for signals defined on regular grids (e.g., 2D images) through the application of an optimal density function to scale the contribution of neighbouring pixels based on their distance from the central pixel. This choice differs from the traditional uniform convolution, which treats all neighbouring pixels equally. Our weighted convolution can be applied to convolutional neural network problems to improve the approximation accuracy. Given a convolutional network, we define a framework to compute the optimal density function through a minimisation model. The framework separates the optimisation of the convolutional kernel weights (using stochastic gradient descent) from the optimisation of the density function (using DIRECT-L). Experimental results on a learning model for an image-to-image task (e.g., image denoising) show that the weighted convolution significantly reduces the loss (up to 53% improvement) and increases the test accuracy compared to standard convolution. While this method increases execution time by 11%, it is robust across several hyperparameters of the learning model. Future work will apply the weighted convolution to real-case 2D and 3D image convolutional learning problems.
title Optimal Density Functions for Weighted Convolution in Learning Models
topic Computer Vision and Pattern Recognition
Machine Learning
42A85
url https://arxiv.org/abs/2505.24527