FlowPalm: Optical Flow Driven Non-Rigid Deformation for Geometrically Diverse Palmprint Generation

CVPR 2026
Yuchen Zou1, Huikai Shao1, Lihuang Fang2, Zhipeng Xiong1, Dexing Zhong1
1 Xi'an Jiaotong University   2 Southern University of Science and Technology
arXiv Code Paper Video Poster Conference

Comparison between Diff-Palm [1] and FlowPalm (Ours). Our FlowPalm is capable of generating palmprints with realistic and flexible geometric variations, faithfully simulating the complex non-rigid deformations observed in real palms.

Abstract

Recently, synthetic palmprints have been increasingly used as substitutes for real data to train recognition models. To be effective, such synthetic data must reflect the diversity of real palmprints, including both style variation and geometric variation. However, existing palmprint generation methods mainly focus on style translation, while geometric variation is either ignored or approximated by simple handcrafted augmentations. In this work, we propose FlowPalm, an optical-flow-driven palmprint generation framework capable of simulating the complex non-rigid deformations observed in real palms. Specifically, FlowPalm estimates optical flows between real palmprint pairs to capture the statistical patterns of geometric deformations. Building on these priors, we design a progressive sampling process that gradually introduces the geometric deformations during diffusion while maintaining identity consistency. Extensive experiments on six benchmark datasets demonstrate that FlowPalm significantly outperforms state-of-the-art palmprint generation approaches in downstream recognition tasks.

Method Overview

We introduce optical flow driven non-rigid deformation modeling to overcome the limitations of handcrafted simple transformations, enabling the synthesis of geometrically diverse and identity-consistent palmprints.

Method Overview

Visualization Results

We visualize the intermediate components of FlowPalm's generation pipeline alongside ablation studies on warped crease and warped noise. Warping only the noise causes the principal lines to remain fixed, while warping only the crease leaves fine texture details unaltered. By simultaneously warping both the crease and the noise, Full Pipeline produces textures whose morphology consistently follows the deformed structure.

Full Pipeline

Deformation Flow

Style Noise

Warped Crease

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Warped Noise

Generated Palmprint

Ablation: w/o Warped Crease

Deformation Flow

Style Noise

Crease (no warp)

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Warped Noise

Result (no warp crease)

Ablation: w/o Warped Noise

Deformation Flow

Style Noise

Warped Crease

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Fixed Noise (no warp)

Result (no warp noise)

BibTeX

@inproceedings{
  zou2026flowpalm,
  title={FlowPalm: Optical Flow Driven Non-Rigid Deformation for Geometrically Diverse Palmprint Generation},
  author={Yuchen Zou and Huikai Shao and Lihuang Fang and Zhipeng Xiong and Dexing Zhong},
  booktitle={Proc. IEEE/CVF Conf. Comput. Vis. Pattern Recognit. (CVPR)},
  year={2026}
}

References

[1] J. Jin, C. Zhao, R. Zhang, S. Shang, J. Xu, J. Zhang, S. M. Wang, Y. Zhao, S. Ding, and W. Jia, "Diff-palm: Realistic palmprint generation with polynomial creases and intra-class variation controllable diffusion models," in Proc. IEEE/CVF Conf. Comput. Vis. Pattern Recognit. (CVPR), 2025, pp. 26367–26376.