AI Article Synopsis
- Temporal compressive coherent diffraction imaging is a lensless technique designed for capturing fast-moving small objects, but struggles with image accuracy due to lost frequency information.
- The dual-domain mean-reverting diffusion model-enhanced method (DMDTC) improves image quality by recovering missing data in both frequency and spatial domains through advanced sample learning.
- DMDTC shows significantly better structural similarity and peak signal-to-noise ratios in reconstructed images compared to traditional methods, offering high temporal frame rates and resolution.
Article Abstract
Temporal compressive coherent diffraction imaging is a lensless imaging technique with the capability to capture fast-moving small objects. However, the accuracy of imaging reconstruction is often hindered by the loss of frequency domain information, a critical factor limiting the quality of the reconstructed images. To improve the quality of these reconstructed images, a method dual-domain mean-reverting diffusion model-enhanced temporal compressive coherent diffraction imaging (DMDTC) has been introduced. DMDTC leverages the mean-reverting diffusion model to acquire prior information in both frequency and spatial domain through sample learning. The frequency domain mean-reverting diffusion model is employed to recover missing information, while hybrid input-output algorithm is carried out to reconstruct the spatial domain image. The spatial domain mean-reverting diffusion model is utilized for denoising and image restoration. DMDTC has demonstrated a significant enhancement in the quality of the reconstructed images. The results indicate that the structural similarity and peak signal-to-noise ratio of images reconstructed by DMDTC surpass those obtained through conventional methods. DMDTC enables high temporal frame rates and high spatial resolution in coherent diffraction imaging.
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| http://dx.doi.org/10.1364/OE.517567 | DOI Listing |
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