Login / Signup

The training process of many deep networks explores the same low-dimensional manifold.

Jialin MaoItay GriniastyHan Kheng TeohRahul RameshRubing YangMark K TranstrumJames P SethnaPratik Chaudhari
Published in: Proceedings of the National Academy of Sciences of the United States of America (2024)
We develop information-geometric techniques to analyze the trajectories of the predictions of deep networks during training. By examining the underlying high-dimensional probabilistic models, we reveal that the training process explores an effectively low-dimensional manifold. Networks with a wide range of architectures, sizes, trained using different optimization methods, regularization techniques, data augmentation techniques, and weight initializations lie on the same manifold in the prediction space. We study the details of this manifold to find that networks with different architectures follow distinguishable trajectories, but other factors have a minimal influence; larger networks train along a similar manifold as that of smaller networks, just faster; and networks initialized at very different parts of the prediction space converge to the solution along a similar manifold.
Keyphrases
  • depressive symptoms
  • healthcare
  • body mass index
  • physical activity
  • virtual reality
  • dna methylation
  • mass spectrometry
  • weight loss
  • health information
  • high resolution
  • high speed