A Comprehensive Review of Deep Learning: Architectures, Recent Advances, and Applications
Deep learning (DL) has become a core component of modern artificial intelligence (AI), driving significant advancements across diverse fields by facilitating the analysis of complex systems, from protein folding in biology to molecular discovery in chemistry and particle interactions in physics. However, the field of deep learning is constantly evolving, with recent innovations in both architectures and applications. Therefore, this paper provides a comprehensive review of recent DL advances, covering the evolut…
The computational analysis of protein structures: Sources, methods, systems and results by Lesk, A.M. Tramontano, A.. Public domain
As of November 27, 2024, this peer-reviewed review paper surveys the state of deep learning, describing its role as a core component of modern AI and summarizing evolution from CNNs and RNNs to transformers, GANs, capsule networks, and GNNs, plus training methods like self-supervised, federated, and deep reinforcement learning.
The synthesis matters because it links architectural and training progress to concrete scientific uses such as protein folding in biology, molecular discovery in chemistry, and particle interactions in physics, while noting that the field is constantly evolving and that current challenges and future directions remain to be addressed.
- Paper reviews evolution and applications of foundational models like convolutional neural networks (CNNs) and Recurrent Neural Networks (RNNs).
- Paper covers recent architectures such as transformers, generative adversarial networks (GANs), capsule networks, and graph neural networks (GNNs).
- Paper discusses novel training techniques including self-supervised learning, federated learning, and deep reinforcement learning.
Deep learning drives advancements in biology, chemistry, and physics by facilitating analysis of protein folding, molecular discovery, and particle interactions.
The rundown
The review synthesizes developments up to November 2024, organizing them into foundational models, newer architectures, and training paradigms.
Foundational coverage includes CNNs and RNNs, while recent architecture coverage includes transformers, GANs, capsule networks, and GNNs.
Training advances highlighted are self-supervised learning, federated learning, and deep reinforcement learning, framed as enhancing model capabilities.
Sources
- Peer-reviewedInformation2024-11-27
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