English

Mode Combinability: Exploring Convex Combinations of Permutation Aligned Models

Machine Learning 2023-08-23 v1

Abstract

We explore element-wise convex combinations of two permutation-aligned neural network parameter vectors ΘA\Theta_A and ΘB\Theta_B of size dd. We conduct extensive experiments by examining various distributions of such model combinations parametrized by elements of the hypercube [0,1]d[0,1]^{d} and its vicinity. Our findings reveal that broad regions of the hypercube form surfaces of low loss values, indicating that the notion of linear mode connectivity extends to a more general phenomenon which we call mode combinability. We also make several novel observations regarding linear mode connectivity and model re-basin. We demonstrate a transitivity property: two models re-based to a common third model are also linear mode connected, and a robustness property: even with significant perturbations of the neuron matchings the resulting combinations continue to form a working model. Moreover, we analyze the functional and weight similarity of model combinations and show that such combinations are non-vacuous in the sense that there are significant functional differences between the resulting models.

Keywords

Cite

@article{arxiv.2308.11511,
  title  = {Mode Combinability: Exploring Convex Combinations of Permutation Aligned Models},
  author = {Adrián Csiszárik and Melinda F. Kiss and Péter Kőrösi-Szabó and Márton Muntag and Gergely Papp and Dániel Varga},
  journal= {arXiv preprint arXiv:2308.11511},
  year   = {2023}
}
R2 v1 2026-06-28T12:01:35.425Z