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Main Authors: Kumar, Mohit, Brucker, Mathias, Valentinitsch, Alexander, Husakovic, Adnan, Abbas, Ali, Geiß, Manuela, Moser, Bernhard A.
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2512.01025
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author Kumar, Mohit
Brucker, Mathias
Valentinitsch, Alexander
Husakovic, Adnan
Abbas, Ali
Geiß, Manuela
Moser, Bernhard A.
author_facet Kumar, Mohit
Brucker, Mathias
Valentinitsch, Alexander
Husakovic, Adnan
Abbas, Ali
Geiß, Manuela
Moser, Bernhard A.
contents Federated learning must address heterogeneity, strict communication and computation limits, and privacy while ensuring performance. We propose an operator-theoretic framework that maps the $L^2$-optimal solution into a reproducing kernel Hilbert space (RKHS) via a forward operator, approximates it using available data, and maps back with the inverse operator, yielding a gradient-free scheme. Finite-sample bounds are derived using concentration inequalities over operator norms, and the framework identifies a data-dependent hypothesis space with guarantees on risk, error, robustness, and approximation. Within this space we design efficient kernel machines leveraging the space folding property of Kernel Affine Hull Machines. Clients transfer knowledge via a scalar space folding measure, reducing communication and enabling a simple differentially private protocol: summaries are computed from noise-perturbed data matrices in one step, avoiding per-round clipping and privacy accounting. The induced global rule requires only integer minimum and equality-comparison operations per test point, making it compatible with fully homomorphic encryption (FHE). Across four benchmarks, the gradient-free FL method with fixed encoder embeddings matches or outperforms strong gradient-based fine-tuning, with gains up to 23.7 points. In differentially private experiments, kernel smoothing mitigates accuracy loss in high-privacy regimes. The global rule admits an FHE realization using $Q \times C$ encrypted minimum and $C$ equality-comparison operations per test point, with operation-level benchmarks showing practical latencies. Overall, the framework provides provable guarantees with low communication, supports private knowledge transfer via scalar summaries, and yields an FHE-compatible prediction rule offering a mathematically grounded alternative to gradient-based federated learning under heterogeneity.
format Preprint
id arxiv_https___arxiv_org_abs_2512_01025
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Operator-Theoretic Framework for Gradient-Free Federated Learning
Kumar, Mohit
Brucker, Mathias
Valentinitsch, Alexander
Husakovic, Adnan
Abbas, Ali
Geiß, Manuela
Moser, Bernhard A.
Machine Learning
Artificial Intelligence
Federated learning must address heterogeneity, strict communication and computation limits, and privacy while ensuring performance. We propose an operator-theoretic framework that maps the $L^2$-optimal solution into a reproducing kernel Hilbert space (RKHS) via a forward operator, approximates it using available data, and maps back with the inverse operator, yielding a gradient-free scheme. Finite-sample bounds are derived using concentration inequalities over operator norms, and the framework identifies a data-dependent hypothesis space with guarantees on risk, error, robustness, and approximation. Within this space we design efficient kernel machines leveraging the space folding property of Kernel Affine Hull Machines. Clients transfer knowledge via a scalar space folding measure, reducing communication and enabling a simple differentially private protocol: summaries are computed from noise-perturbed data matrices in one step, avoiding per-round clipping and privacy accounting. The induced global rule requires only integer minimum and equality-comparison operations per test point, making it compatible with fully homomorphic encryption (FHE). Across four benchmarks, the gradient-free FL method with fixed encoder embeddings matches or outperforms strong gradient-based fine-tuning, with gains up to 23.7 points. In differentially private experiments, kernel smoothing mitigates accuracy loss in high-privacy regimes. The global rule admits an FHE realization using $Q \times C$ encrypted minimum and $C$ equality-comparison operations per test point, with operation-level benchmarks showing practical latencies. Overall, the framework provides provable guarantees with low communication, supports private knowledge transfer via scalar summaries, and yields an FHE-compatible prediction rule offering a mathematically grounded alternative to gradient-based federated learning under heterogeneity.
title Operator-Theoretic Framework for Gradient-Free Federated Learning
topic Machine Learning
Artificial Intelligence
url https://arxiv.org/abs/2512.01025