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Main Authors: Jia, Zexi, Luo, Pengcheng, Fang, Zhengyao, Zhang, Jinchao, Zhou, Jie
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2603.11509
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author Jia, Zexi
Luo, Pengcheng
Fang, Zhengyao
Zhang, Jinchao
Zhou, Jie
author_facet Jia, Zexi
Luo, Pengcheng
Fang, Zhengyao
Zhang, Jinchao
Zhou, Jie
contents Classifier-Free Guidance (CFG) serves as the de facto control mechanism for conditional diffusion, yet high guidance scales notoriously induce oversaturation, texture artifacts, and structural collapse. We attribute this failure to a geometric mismatch: standard CFG performs Euclidean extrapolation in ambient space, inadvertently driving sampling trajectories off the high-density data manifold. To resolve this, we present Manifold-Optimal Guidance (MOG), a framework that reformulates guidance as a local optimal control problem. MOG yields a closed-form, geometry-aware Riemannian update that corrects off-manifold drift without requiring retraining. Leveraging this perspective, we further introduce Auto-MOG, a dynamic energy-balancing schedule that adaptively calibrates guidance strength, effectively eliminating the need for manual hyperparameter tuning. Extensive validation demonstrates that MOG yields superior fidelity and alignment compared to baselines, with virtually no added computational overhead.
format Preprint
id arxiv_https___arxiv_org_abs_2603_11509
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Manifold-Optimal Guidance: A Unified Riemannian Control View of Diffusion Guidance
Jia, Zexi
Luo, Pengcheng
Fang, Zhengyao
Zhang, Jinchao
Zhou, Jie
Computer Vision and Pattern Recognition
Classifier-Free Guidance (CFG) serves as the de facto control mechanism for conditional diffusion, yet high guidance scales notoriously induce oversaturation, texture artifacts, and structural collapse. We attribute this failure to a geometric mismatch: standard CFG performs Euclidean extrapolation in ambient space, inadvertently driving sampling trajectories off the high-density data manifold. To resolve this, we present Manifold-Optimal Guidance (MOG), a framework that reformulates guidance as a local optimal control problem. MOG yields a closed-form, geometry-aware Riemannian update that corrects off-manifold drift without requiring retraining. Leveraging this perspective, we further introduce Auto-MOG, a dynamic energy-balancing schedule that adaptively calibrates guidance strength, effectively eliminating the need for manual hyperparameter tuning. Extensive validation demonstrates that MOG yields superior fidelity and alignment compared to baselines, with virtually no added computational overhead.
title Manifold-Optimal Guidance: A Unified Riemannian Control View of Diffusion Guidance
topic Computer Vision and Pattern Recognition
url https://arxiv.org/abs/2603.11509