We develop a kernel method for generative modeling within the stochastic interpolant framework, replacing neural network training with linear systems. The drift of the generative SDE is b^t(x)=∇ϕ(x)⊤ηt, where ηt∈RP solves a P×P system computable from data, with P independent of the data dimension d. Since estimates are inexact, the diffusion coefficient Dt affects sample quality; the optimal Dt∗ from Girsanov diverges at t=0, but this poses no difficulty and we develop an integrator that handles it seamlessly. The framework accommodates diverse feature maps -- scattering transforms, pretrained generative models etc. -- enabling training-free generation and model combination. We demonstrate the approach on financial time series, turbulence, and image generation.
Cite
@article{arxiv.2602.20070,
title = {Training-Free Generative Modeling via Kernelized Stochastic Interpolants},
author = {Florentin Coeurdoux and Etienne Lempereur and Nathanaël Cuvelle-Magar and Thomas Eboli and Stéphane Mallat and Anastasia Borovykh and Eric Vanden-Eijnden},
journal= {arXiv preprint arXiv:2602.20070},
year = {2026}
}