Proposes TCD, a three-step conditional diffusion model with ICD module, claiming superior fidelity and generalization for LFM 3D reconstruction.
3D Gaussian Adaptive Reconstruction for Fourier Light-Field Microscopy
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abstract
Compared to light-field microscopy (LFM), which enables high-speed volumetric imaging but suffers from non-uniform spatial sampling, Fourier light-field microscopy (FLFM) introduces sub-aperture division at the pupil plane, thereby ensuring spatially invariant sampling and enhancing spatial resolution. Conventional FLFM reconstruction methods, such as Richardson-Lucy (RL) deconvolution, exhibit poor axial resolution and signal degradation due to the ill-posed nature of the inverse problem. While data-driven approaches enhance spatial resolution by leveraging high-quality paired datasets or imposing structural priors, Neural Radiance Fields (NeRF)-based methods employ physics-informed self-supervised learning to overcome these limitations, yet they are hindered by substantial computational costs and memory demands. Therefore, we propose 3D Gaussian Adaptive Tomography (3DGAT) for FLFM, a 3D gaussian splatting based self-supervised learning framework that significantly improves the volumetric reconstruction quality of FLFM while maintaining computational efficiency. Experimental results indicate that our approach achieves higher resolution and improved reconstruction accuracy, highlighting its potential to advance FLFM imaging and broaden its applications in 3D optical microscopy.
fields
cs.CV 1years
2026 1verdicts
UNVERDICTED 1representative citing papers
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Three-Step Conditional Diffusion 3D Reconstruction for Light-Field Microscopy
Proposes TCD, a three-step conditional diffusion model with ICD module, claiming superior fidelity and generalization for LFM 3D reconstruction.