High-dimensional manifold of solutions in neural networks: insights from statistical physics

In these pedagogic notes I review the statistical mechanics approach to neural networks, focusing on the paradigmatic example of the perceptron architecture with binary an continuous weights, in the classification setting. I will review the Gardner's approach based on replica method and the derivation of the SAT/UNSAT transition in the storage setting. Then, I discuss some recent works that unveiled how the zero training error configurations are geometrically arranged, and how this arrangement changes as the size of the training set increases. I also illustrate how different regions of solution space can be explored analytically and how the landscape in the vicinity of a solution can be characterized. I give evidence how, in binary weight models, algorithmic hardness is a consequence of the disappearance of a clustered region of solutions that extends to very large distances. Finally, I demonstrate how the study of linear mode connectivity between solutions can give insights into the average shape of the solution manifold.

@article{malatesta2025_2309.09240,
  title={ High-dimensional manifold of solutions in neural networks: insights from statistical physics },
  author={ Enrico M. Malatesta },
  journal={arXiv preprint arXiv:2309.09240},
  year={ 2025 }
}