English

Generalized Shape Metrics on Neural Representations

Machine Learning 2022-01-14 v2 Machine Learning

Abstract

Understanding the operation of biological and artificial networks remains a difficult and important challenge. To identify general principles, researchers are increasingly interested in surveying large collections of networks that are trained on, or biologically adapted to, similar tasks. A standardized set of analysis tools is now needed to identify how network-level covariates -- such as architecture, anatomical brain region, and model organism -- impact neural representations (hidden layer activations). Here, we provide a rigorous foundation for these analyses by defining a broad family of metric spaces that quantify representational dissimilarity. Using this framework we modify existing representational similarity measures based on canonical correlation analysis to satisfy the triangle inequality, formulate a novel metric that respects the inductive biases in convolutional layers, and identify approximate Euclidean embeddings that enable network representations to be incorporated into essentially any off-the-shelf machine learning method. We demonstrate these methods on large-scale datasets from biology (Allen Institute Brain Observatory) and deep learning (NAS-Bench-101). In doing so, we identify relationships between neural representations that are interpretable in terms of anatomical features and model performance.

Keywords

Cite

@article{arxiv.2110.14739,
  title  = {Generalized Shape Metrics on Neural Representations},
  author = {Alex H. Williams and Erin Kunz and Simon Kornblith and Scott W. Linderman},
  journal= {arXiv preprint arXiv:2110.14739},
  year   = {2022}
}

Comments

26 pages, 7 figures, NeurIPS 2021

R2 v1 2026-06-24T07:14:52.587Z