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Main Authors: Zhang, Jiahan, Zhang, Yaoyu, Luo, Tao
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2505.12419
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author Zhang, Jiahan
Zhang, Yaoyu
Luo, Tao
author_facet Zhang, Jiahan
Zhang, Yaoyu
Luo, Tao
contents In this paper, we study the Karush-Kuhn-Tucker (KKT) points of the associated maximum-margin problem in homogeneous neural networks, including fully-connected and convolutional neural networks. In particular, We investigates the relationship between such KKT points across networks of different widths generated. We introduce and formalize the \textbf{KKT point embedding principle}, establishing that KKT points of a homogeneous network's max-margin problem ($P_Φ$) can be embedded into the KKT points of a larger network's problem ($P_{\tildeΦ}$) via specific linear isometric transformations. We rigorously prove this principle holds for neuron splitting in fully-connected networks and channel splitting in convolutional neural networks. Furthermore, we connect this static embedding to the dynamics of gradient flow training with smooth losses. We demonstrate that trajectories initiated from appropriately mapped points remain mapped throughout training and that the resulting $ω$-limit sets of directions are correspondingly mapped, thereby preserving the alignment with KKT directions dynamically when directional convergence occurs. We conduct several experiments to justify that trajectories are preserved. Our findings offer insights into the effects of network width, parameter redundancy, and the structural connections between solutions found via optimization in homogeneous networks of varying sizes.
format Preprint
id arxiv_https___arxiv_org_abs_2505_12419
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Embedding principle of homogeneous neural network for classification problem
Zhang, Jiahan
Zhang, Yaoyu
Luo, Tao
Machine Learning
In this paper, we study the Karush-Kuhn-Tucker (KKT) points of the associated maximum-margin problem in homogeneous neural networks, including fully-connected and convolutional neural networks. In particular, We investigates the relationship between such KKT points across networks of different widths generated. We introduce and formalize the \textbf{KKT point embedding principle}, establishing that KKT points of a homogeneous network's max-margin problem ($P_Φ$) can be embedded into the KKT points of a larger network's problem ($P_{\tildeΦ}$) via specific linear isometric transformations. We rigorously prove this principle holds for neuron splitting in fully-connected networks and channel splitting in convolutional neural networks. Furthermore, we connect this static embedding to the dynamics of gradient flow training with smooth losses. We demonstrate that trajectories initiated from appropriately mapped points remain mapped throughout training and that the resulting $ω$-limit sets of directions are correspondingly mapped, thereby preserving the alignment with KKT directions dynamically when directional convergence occurs. We conduct several experiments to justify that trajectories are preserved. Our findings offer insights into the effects of network width, parameter redundancy, and the structural connections between solutions found via optimization in homogeneous networks of varying sizes.
title Embedding principle of homogeneous neural network for classification problem
topic Machine Learning
url https://arxiv.org/abs/2505.12419