Connecting the Dots: Exploring the Fundamental Underpinnings of Deep Learning
DOI:
https://doi.org/10.47363/JAICC/2025(4)440Keywords:
Deep Learning, Diffraction, Neural Networks, Talbot Effect, Wavelet Transforms, Wave PropagationAbstract
Deep learning has transformed various sectors, introducing new applications and opportunities. However, the underlying physical mechanisms or mathematical theories responsible for its success remain fundamental questions. This inquiry explores the connection between deep learning algorithms and established scientific principles with the aim of uncovering the mysteries behind their remarkable capabilities. By bridging the gap between deep learning, neural networks, and scientific knowledge, we can develop robust and interpretable models with enhanced capabilities. This ongoing research involves collaboration across diverse fields to unveil the hidden intricacies of deep learning algorithms and their links to physical phenomena. The ultimate goal is to contribute to the potential of the journal by examining the theory, design and application of neural networks and machine learning, focusing on the effectiveness of neural network paradigms for deep learning and their connections to physical events. By examining the intersection of deep learning,
neural networks, and physical phenomena, we aim to advance our understanding and use of neural networks and machine learning in many areas of space, pushing the boundaries of excellence in science and engineering
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Copyright (c) 2025 Journal of Artificial Intelligence & Cloud Computing
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