Abstract
The study on DDPM demonstrates that it has potential for image generation, but its limitations must be addressed. The slow sampling speed remains a significant issue, as it limits the model's applicability in real-time settings. The authors' implementation of the DPM-solver sampler represents an important step towards addressing this problem. The results indicate that using the DPM-solver can greatly improve the sampling speed without sacrificing too much quality in the generated samples. The authors also explore some specific applications of DDPM, providing further insights into its capabilities and limitations. For instance, the study demonstrates that DDPM can be used for image inpainting and super-resolution tasks, enabling applications like image restoration and upscaling. However, the study also reveals that DDPM may struggle to generate high-quality images on some datasets or for specific tasks, indicating that there is still much room for improvement. Overall, the study highlights the strengths and weaknesses of DDPM and presents a promising direction for future research in diffusion models. The improved sampling speed achieved through the DPM-solver sampler could open up new possibilities for utilizing DDPM in real-world applications.
Publisher
Darcy & Roy Press Co. Ltd.
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