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Main Authors: Zini, Julia El, Musharrafieh, Bassel, Awad, Mariette
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2401.04141
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author Zini, Julia El
Musharrafieh, Bassel
Awad, Mariette
author_facet Zini, Julia El
Musharrafieh, Bassel
Awad, Mariette
contents The fractal dimension provides a statistical index of object complexity by studying how the pattern changes with the measuring scale. Although useful in several classification tasks, the fractal dimension is under-explored in deep learning applications. In this work, we investigate the features that are learned by deep models and we study whether these deep networks are able to encode features as complex and high-level as the fractal dimensions. Specifically, we conduct a correlation analysis experiment to show that deep networks are not able to extract such a feature in none of their layers. We combine our analytical study with a human evaluation to investigate the differences between deep learning networks and models that operate on the fractal feature solely. Moreover, we show the effectiveness of fractal features in applications where the object structure is crucial for the classification task. We empirically show that training a shallow network on fractal features achieves performance comparable, even superior in specific cases, to that of deep networks trained on raw data while requiring less computational resources. Fractals improved the accuracy of the classification by 30% on average while requiring up to 84% less time to train. We couple our empirical study with a complexity analysis of the computational cost of extracting the proposed fractal features, and we study its limitation.
format Preprint
id arxiv_https___arxiv_org_abs_2401_04141
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle On The Potential of The Fractal Geometry and The CNNs Ability to Encode it
Zini, Julia El
Musharrafieh, Bassel
Awad, Mariette
Machine Learning
Artificial Intelligence
The fractal dimension provides a statistical index of object complexity by studying how the pattern changes with the measuring scale. Although useful in several classification tasks, the fractal dimension is under-explored in deep learning applications. In this work, we investigate the features that are learned by deep models and we study whether these deep networks are able to encode features as complex and high-level as the fractal dimensions. Specifically, we conduct a correlation analysis experiment to show that deep networks are not able to extract such a feature in none of their layers. We combine our analytical study with a human evaluation to investigate the differences between deep learning networks and models that operate on the fractal feature solely. Moreover, we show the effectiveness of fractal features in applications where the object structure is crucial for the classification task. We empirically show that training a shallow network on fractal features achieves performance comparable, even superior in specific cases, to that of deep networks trained on raw data while requiring less computational resources. Fractals improved the accuracy of the classification by 30% on average while requiring up to 84% less time to train. We couple our empirical study with a complexity analysis of the computational cost of extracting the proposed fractal features, and we study its limitation.
title On The Potential of The Fractal Geometry and The CNNs Ability to Encode it
topic Machine Learning
Artificial Intelligence
url https://arxiv.org/abs/2401.04141