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Autori principali: Yu, Zhuohang, An, Ling, Li, Yansong, Wu, Yu, Dong, Zeyu, Liu, Zhangdi, Gao, Le, Zhang, Zhenyu, Zhou, Chichun
Natura: Preprint
Pubblicazione: 2024
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Accesso online:https://arxiv.org/abs/2411.08164
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author Yu, Zhuohang
An, Ling
Li, Yansong
Wu, Yu
Dong, Zeyu
Liu, Zhangdi
Gao, Le
Zhang, Zhenyu
Zhou, Chichun
author_facet Yu, Zhuohang
An, Ling
Li, Yansong
Wu, Yu
Dong, Zeyu
Liu, Zhangdi
Gao, Le
Zhang, Zhenyu
Zhou, Chichun
contents Conventional methods, including Decision Tree (DT)-based methods, have been effective in scientific tasks, such as non-image medical diagnostics, system anomaly detection, and inorganic catalysis efficiency prediction. However, most deep-learning techniques have struggled to surpass or even match this level of success as traditional machine-learning methods. The primary reason is that these applications involve multi-source, heterogeneous data where features lack explicit relationships. This contrasts with image data, where pixels exhibit spatial relationships; textual data, where words have sequential dependencies; and graph data, where nodes are connected through established associations. The absence of explicit Feature Relation Patterns (FRPs) presents a significant challenge for deep learning techniques in scientific applications that are not image, text, and graph-based. In this paper, we introduce EAPCR, a universal feature extractor designed for data without explicit FRPs. Tested across various scientific tasks, EAPCR consistently outperforms traditional methods and bridges the gap where deep learning models fall short. To further demonstrate its robustness, we synthesize a dataset without explicit FRPs. While Kolmogorov-Arnold Network (KAN) and feature extractors like Convolutional Neural Networks (CNNs), Graph Convolutional Networks (GCNs), and Transformers struggle, EAPCR excels, demonstrating its robustness and superior performance in scientific tasks without FRPs.
format Preprint
id arxiv_https___arxiv_org_abs_2411_08164
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle EAPCR: A Universal Feature Extractor for Scientific Data without Explicit Feature Relation Patterns
Yu, Zhuohang
An, Ling
Li, Yansong
Wu, Yu
Dong, Zeyu
Liu, Zhangdi
Gao, Le
Zhang, Zhenyu
Zhou, Chichun
Machine Learning
Computer Vision and Pattern Recognition
Conventional methods, including Decision Tree (DT)-based methods, have been effective in scientific tasks, such as non-image medical diagnostics, system anomaly detection, and inorganic catalysis efficiency prediction. However, most deep-learning techniques have struggled to surpass or even match this level of success as traditional machine-learning methods. The primary reason is that these applications involve multi-source, heterogeneous data where features lack explicit relationships. This contrasts with image data, where pixels exhibit spatial relationships; textual data, where words have sequential dependencies; and graph data, where nodes are connected through established associations. The absence of explicit Feature Relation Patterns (FRPs) presents a significant challenge for deep learning techniques in scientific applications that are not image, text, and graph-based. In this paper, we introduce EAPCR, a universal feature extractor designed for data without explicit FRPs. Tested across various scientific tasks, EAPCR consistently outperforms traditional methods and bridges the gap where deep learning models fall short. To further demonstrate its robustness, we synthesize a dataset without explicit FRPs. While Kolmogorov-Arnold Network (KAN) and feature extractors like Convolutional Neural Networks (CNNs), Graph Convolutional Networks (GCNs), and Transformers struggle, EAPCR excels, demonstrating its robustness and superior performance in scientific tasks without FRPs.
title EAPCR: A Universal Feature Extractor for Scientific Data without Explicit Feature Relation Patterns
topic Machine Learning
Computer Vision and Pattern Recognition
url https://arxiv.org/abs/2411.08164