English

DEFT: Efficient Fine-Tuning of Diffusion Models by Learning the Generalised $h$-transform

Machine Learning 2025-05-22 v5

Abstract

Generative modelling paradigms based on denoising diffusion processes have emerged as a leading candidate for conditional sampling in inverse problems. In many real-world applications, we often have access to large, expensively trained unconditional diffusion models, which we aim to exploit for improving conditional sampling. Most recent approaches are motivated heuristically and lack a unifying framework, obscuring connections between them. Further, they often suffer from issues such as being very sensitive to hyperparameters, being expensive to train or needing access to weights hidden behind a closed API. In this work, we unify conditional training and sampling using the mathematically well-understood Doob's h-transform. This new perspective allows us to unify many existing methods under a common umbrella. Under this framework, we propose DEFT (Doob's h-transform Efficient FineTuning), a new approach for conditional generation that simply fine-tunes a very small network to quickly learn the conditional hh-transform, while keeping the larger unconditional network unchanged. DEFT is much faster than existing baselines while achieving state-of-the-art performance across a variety of linear and non-linear benchmarks. On image reconstruction tasks, we achieve speedups of up to 1.6×\times, while having the best perceptual quality on natural images and reconstruction performance on medical images. Further, we also provide initial experiments on protein motif scaffolding and outperform reconstruction guidance methods.

Keywords

Cite

@article{arxiv.2406.01781,
  title  = {DEFT: Efficient Fine-Tuning of Diffusion Models by Learning the Generalised $h$-transform},
  author = {Alexander Denker and Francisco Vargas and Shreyas Padhy and Kieran Didi and Simon Mathis and Vincent Dutordoir and Riccardo Barbano and Emile Mathieu and Urszula Julia Komorowska and Pietro Lio},
  journal= {arXiv preprint arXiv:2406.01781},
  year   = {2025}
}

Comments

arXiv admin note: text overlap with arXiv:2312.09236

R2 v1 2026-06-28T16:52:01.167Z