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- 首页 >> Python编程 Generative Models for Visual Signals – Assignment
I. Introduction:
This homework assignment is focused on providing a deep understanding of two advanced image processing
models: Denoising Diffusion Probabilistic Models (DDPM) and Deep Image Prior (DIP). This document will
elaborate on the core concepts, theoretical underpinnings, and practical examples to better grasp how these
models operate and can be applied in real-world scenarios.
1.1. Denoising Diffusion Probabilistic Models (DDPM)
DDPMs are generative models that transform Gaussian noise into a complex data distribution through a process
akin to reversing thermodynamic diffusion. This is achieved by a sequence of learnable reverse diffusion steps,
each of which is conditioned on its predecessor. The models are trained to predict the noise added at each timestep,
enabling the recovery of the original data from pure noise. For instance, one practical application is generating
detailed and diverse human faces from randomized noise inputs.
A simplified equation representing this process is: x_t = sqrt(alpha_t) * x_0 + sqrt(1-alpha_t) * epsilon, where
epsilon is noise, and alpha_t represents the variance schedule over timesteps.
1.2. Deep Image Prior (DIP)
Deep Image Prior utilizes the inherent structure of convolutional neural networks (CNNs) to encode priors for
natural images. By fitting a CNN with randomly initialized weights directly to a target image, DIP leverages the
bias of CNNs towards natural image statistics without training on large datasets. This approach is particularly
effective for tasks like image denoising, super-resolution, and inpainting, providing high-quality restorations
based on the network's innate biases alone.
The optimization process can be described as minimizing the difference between the CNN output and the target
image, which typically leads to underfitting to noise and emphasizes significant image structures.
II. Task: Technical Integration of DDPM and DIP
For this assignment, you are tasked to explore and propose methods to integrate the principles of DDPM and DIP.
Consider how the probabilistic modeling of DDPM can enhance the image-specific priors of DIP, or how the
architectural bias of DIP can be used to initiate the reverse diffusion process in DDPM. Provide theoretical
formulations and possible practical implementations. Here are two examples, and your solution could be one of
them or a novel one.
Example 1: Accelerating DDPM with DIP-based Initial Priors
In this example, you are asked to explore the possibility of using Deep Image Prior (DIP) to provide a quick initial
prior for the Denoising Diffusion Probabilistic Model (DDPM) training process. The motivation behind this
approach is to address the slow backward learning process in DDPM by leveraging the image-specific prior
automatically learned by the CNN architecture in DIP. To implement this idea, you can start by training a DIP model on the target image for a relatively short period.
The goal is to capture the high-level structures and patterns present in the image without overfitting to the noise.
The trained DIP model can then be used to generate an initial prior for the DDPM training process.
Next, you should modify the DDPM training algorithm to incorporate the DIP-based initial prior. Instead of
starting from pure noise, the DDPM model can be initialized with the output of the DIP model. This initialization
can provide a more informative starting point, potentially reducing the number of diffusion steps required for the
DDPM model to converge.
You should experiment with different DIP training durations and architectures to find the optimal balance
between capturing meaningful image priors and computational efficiency. They should also investigate the impact
of the DIP-based initialization on the quality and diversity of the generated samples from the DDPM model.
To evaluate the effectiveness of this approach, you can compare the convergence speed and sample quality of the
DDPM model with and without the DIP-based initial prior. They should provide quantitative metrics, such as the
number of diffusion steps required to reach a certain level of sample quality, as well as qualitative comparisons of
the generated samples. Furthermore, you can explore variations of this idea, such as using DIP to provide
intermediate priors at different stages of the DDPM training process. They can also investigate the potential of
using DIP to guide the noise estimation and denoising steps in DDPM, leveraging the learned image prior to
improve the accuracy of these steps.
Example 2: Guiding DIP Early Stopping with DDPM-inspired Supervision
In this example, you are challenged to develop a more principled approach to determine the optimal early
stopping point in Deep Image Prior (DIP) training by incorporating supervision information inspired by the
Denoising Diffusion Probabilistic Model (DDPM).
The main idea is to introduce gradual denoising steps during the DIP training process, similar to the denoising
steps in DDPM. By adding noise to the target image at different levels and using these noisy versions as
intermediate targets, you can guide the DIP model to learn a hierarchical representation of the image.
To implement this approach, you should modify the DIP training algorithm to include multiple denoising stages.
At each stage, the target image is corrupted with noise of varying levels, creating a sequence of noisy images. The
DIP model is then trained to reconstruct these noisy images in a progressive manner, starting from the most
heavily corrupted image and gradually moving towards the clean target image.
During training, you should monitor the reconstruction quality of the DIP model at each denoising stage. They
can use metrics such as peak signal-to-noise ratio (PSNR) or structural similarity index (SSIM) to quantify the
similarity between the reconstructed images and the corresponding noisy targets. By analyzing the improvement
in reconstruction quality across the denoising stages, you can develop a criterion for determining the optimal
stopping point for DIP training.
You should experiment with different noise levels, denoising schedules, and DIP architectures to find the most
effective configuration. They should also investigate the impact of this approach on the final reconstructed image
quality and compare it with traditional early stopping methods used in DIP.
Furthermore, you can explore additional techniques to enhance the denoising guidance in DIP training. For
example, they can incorporate perceptual loss functions or adversarial training objectives to improve the
perceptual quality of the reconstructed images. They can also investigate the use of learned denoising priors or
conditional denoising models to guide the DIP training process.
To evaluate the effectiveness of this approach, you should provide quantitative comparisons of the reconstruction
quality and early stopping accuracy compared to baseline DIP methods. They should also present qualitative
results showcasing the visual quality of the reconstructed images at different denoising stages and the final output.
III. Evaluation Criteria
Theoretical Justification (30%):
Provide a clear and coherent explanation of the proposed solution, highlighting how it combines the
strengths of DDPM and DIP. Justify the design choices and assumptions made in the proposed
approach. Discuss the potential benefits and limitations of the proposed solution compared to using
DDPM or DIP alone.
Experimental Verification (40%):
Implement the proposed solution and conduct experiments to validate its effectiveness. Compare the
performance of the proposed approach with standalone DDPM and DIP methods in terms of either
image quality, generation speed, or both. Provide quantitative metrics to support the claims, such as
PSNR, SSIM, FID, or generation time. Present qualitative results showcasing the visual quality of the
generated or reconstructed images. Analyze the experimental results and discuss the observed
improvements or trade-offs compared to the baseline methods.
Ablation Studies and Analysis (30%):
Conduct ablation studies to investigate the impact of different components or hyperparameters in the
proposed solution. Vary the key parameters, such as noise levels, denoising schedules, or architectures,
and evaluate their influence on the performance. Provide insights and interpretations based on the
ablation studies, justifying the chosen configurations.
Note: The focus of this assignment is on demonstrating the effectiveness of combining DDPM and DIP
techniques, rather than achieving state-of-the-art performance. The proposed solution should show improvements
in either image quality, generation speed, or both, compared to using DDPM or DIP individually. The claims
made in the solution should be supported by theoretical justifications and experimental verification.
The evaluation criteria emphasize the importance of providing a clear theoretical justification for the proposed
approach, conducting thorough experiments to validate its effectiveness, and presenting the work in a wellorganized
and understandable manner. You are expected to provide quantitative and qualitative results, perform
ablation studies to analyze the impact of different components, and discuss the observed improvements or tradeoffs
compared to the baseline methods.
By meeting these evaluation criteria, you can demonstrate their understanding of the DDPM and DIP techniques,
their ability to combine them effectively, and their skills in conducting rigorous experiments and analysis.
IV. Submission Requirements
4.1. GitHub Repository (50%):
Create a GitHub repository to host your implementation and related files.
Include well-documented and organized code for your proposed solution.
Provide clear instructions in the README.md file on how to run the code and reproduce the experiments.
Use appropriate git commit messages and branches to track the development progress.
Ensure that the repository is accessible to the instructor and teaching assistants.
4.2. Report (50%):
Write a comprehensive report describing your proposed solution, experiments, and findings.
The report should be in a format of your choice (e.g., PDF, Markdown, LaTeX) and can be written in any
preferred language.
4.3. Submission Deadline:
The GitHub repository link and the report should be submitted via Moodle by 2024.6.11.
Late submissions will be subject to the course's late submission policy.
I. Introduction:
This homework assignment is focused on providing a deep understanding of two advanced image processing
models: Denoising Diffusion Probabilistic Models (DDPM) and Deep Image Prior (DIP). This document will
elaborate on the core concepts, theoretical underpinnings, and practical examples to better grasp how these
models operate and can be applied in real-world scenarios.
1.1. Denoising Diffusion Probabilistic Models (DDPM)
DDPMs are generative models that transform Gaussian noise into a complex data distribution through a process
akin to reversing thermodynamic diffusion. This is achieved by a sequence of learnable reverse diffusion steps,
each of which is conditioned on its predecessor. The models are trained to predict the noise added at each timestep,
enabling the recovery of the original data from pure noise. For instance, one practical application is generating
detailed and diverse human faces from randomized noise inputs.
A simplified equation representing this process is: x_t = sqrt(alpha_t) * x_0 + sqrt(1-alpha_t) * epsilon, where
epsilon is noise, and alpha_t represents the variance schedule over timesteps.
1.2. Deep Image Prior (DIP)
Deep Image Prior utilizes the inherent structure of convolutional neural networks (CNNs) to encode priors for
natural images. By fitting a CNN with randomly initialized weights directly to a target image, DIP leverages the
bias of CNNs towards natural image statistics without training on large datasets. This approach is particularly
effective for tasks like image denoising, super-resolution, and inpainting, providing high-quality restorations
based on the network's innate biases alone.
The optimization process can be described as minimizing the difference between the CNN output and the target
image, which typically leads to underfitting to noise and emphasizes significant image structures.
II. Task: Technical Integration of DDPM and DIP
For this assignment, you are tasked to explore and propose methods to integrate the principles of DDPM and DIP.
Consider how the probabilistic modeling of DDPM can enhance the image-specific priors of DIP, or how the
architectural bias of DIP can be used to initiate the reverse diffusion process in DDPM. Provide theoretical
formulations and possible practical implementations. Here are two examples, and your solution could be one of
them or a novel one.
Example 1: Accelerating DDPM with DIP-based Initial Priors
In this example, you are asked to explore the possibility of using Deep Image Prior (DIP) to provide a quick initial
prior for the Denoising Diffusion Probabilistic Model (DDPM) training process. The motivation behind this
approach is to address the slow backward learning process in DDPM by leveraging the image-specific prior
automatically learned by the CNN architecture in DIP. To implement this idea, you can start by training a DIP model on the target image for a relatively short period.
The goal is to capture the high-level structures and patterns present in the image without overfitting to the noise.
The trained DIP model can then be used to generate an initial prior for the DDPM training process.
Next, you should modify the DDPM training algorithm to incorporate the DIP-based initial prior. Instead of
starting from pure noise, the DDPM model can be initialized with the output of the DIP model. This initialization
can provide a more informative starting point, potentially reducing the number of diffusion steps required for the
DDPM model to converge.
You should experiment with different DIP training durations and architectures to find the optimal balance
between capturing meaningful image priors and computational efficiency. They should also investigate the impact
of the DIP-based initialization on the quality and diversity of the generated samples from the DDPM model.
To evaluate the effectiveness of this approach, you can compare the convergence speed and sample quality of the
DDPM model with and without the DIP-based initial prior. They should provide quantitative metrics, such as the
number of diffusion steps required to reach a certain level of sample quality, as well as qualitative comparisons of
the generated samples. Furthermore, you can explore variations of this idea, such as using DIP to provide
intermediate priors at different stages of the DDPM training process. They can also investigate the potential of
using DIP to guide the noise estimation and denoising steps in DDPM, leveraging the learned image prior to
improve the accuracy of these steps.
Example 2: Guiding DIP Early Stopping with DDPM-inspired Supervision
In this example, you are challenged to develop a more principled approach to determine the optimal early
stopping point in Deep Image Prior (DIP) training by incorporating supervision information inspired by the
Denoising Diffusion Probabilistic Model (DDPM).
The main idea is to introduce gradual denoising steps during the DIP training process, similar to the denoising
steps in DDPM. By adding noise to the target image at different levels and using these noisy versions as
intermediate targets, you can guide the DIP model to learn a hierarchical representation of the image.
To implement this approach, you should modify the DIP training algorithm to include multiple denoising stages.
At each stage, the target image is corrupted with noise of varying levels, creating a sequence of noisy images. The
DIP model is then trained to reconstruct these noisy images in a progressive manner, starting from the most
heavily corrupted image and gradually moving towards the clean target image.
During training, you should monitor the reconstruction quality of the DIP model at each denoising stage. They
can use metrics such as peak signal-to-noise ratio (PSNR) or structural similarity index (SSIM) to quantify the
similarity between the reconstructed images and the corresponding noisy targets. By analyzing the improvement
in reconstruction quality across the denoising stages, you can develop a criterion for determining the optimal
stopping point for DIP training.
You should experiment with different noise levels, denoising schedules, and DIP architectures to find the most
effective configuration. They should also investigate the impact of this approach on the final reconstructed image
quality and compare it with traditional early stopping methods used in DIP.
Furthermore, you can explore additional techniques to enhance the denoising guidance in DIP training. For
example, they can incorporate perceptual loss functions or adversarial training objectives to improve the
perceptual quality of the reconstructed images. They can also investigate the use of learned denoising priors or
conditional denoising models to guide the DIP training process.
To evaluate the effectiveness of this approach, you should provide quantitative comparisons of the reconstruction
quality and early stopping accuracy compared to baseline DIP methods. They should also present qualitative
results showcasing the visual quality of the reconstructed images at different denoising stages and the final output.
III. Evaluation Criteria
Theoretical Justification (30%):
Provide a clear and coherent explanation of the proposed solution, highlighting how it combines the
strengths of DDPM and DIP. Justify the design choices and assumptions made in the proposed
approach. Discuss the potential benefits and limitations of the proposed solution compared to using
DDPM or DIP alone.
Experimental Verification (40%):
Implement the proposed solution and conduct experiments to validate its effectiveness. Compare the
performance of the proposed approach with standalone DDPM and DIP methods in terms of either
image quality, generation speed, or both. Provide quantitative metrics to support the claims, such as
PSNR, SSIM, FID, or generation time. Present qualitative results showcasing the visual quality of the
generated or reconstructed images. Analyze the experimental results and discuss the observed
improvements or trade-offs compared to the baseline methods.
Ablation Studies and Analysis (30%):
Conduct ablation studies to investigate the impact of different components or hyperparameters in the
proposed solution. Vary the key parameters, such as noise levels, denoising schedules, or architectures,
and evaluate their influence on the performance. Provide insights and interpretations based on the
ablation studies, justifying the chosen configurations.
Note: The focus of this assignment is on demonstrating the effectiveness of combining DDPM and DIP
techniques, rather than achieving state-of-the-art performance. The proposed solution should show improvements
in either image quality, generation speed, or both, compared to using DDPM or DIP individually. The claims
made in the solution should be supported by theoretical justifications and experimental verification.
The evaluation criteria emphasize the importance of providing a clear theoretical justification for the proposed
approach, conducting thorough experiments to validate its effectiveness, and presenting the work in a wellorganized
and understandable manner. You are expected to provide quantitative and qualitative results, perform
ablation studies to analyze the impact of different components, and discuss the observed improvements or tradeoffs
compared to the baseline methods.
By meeting these evaluation criteria, you can demonstrate their understanding of the DDPM and DIP techniques,
their ability to combine them effectively, and their skills in conducting rigorous experiments and analysis.
IV. Submission Requirements
4.1. GitHub Repository (50%):
Create a GitHub repository to host your implementation and related files.
Include well-documented and organized code for your proposed solution.
Provide clear instructions in the README.md file on how to run the code and reproduce the experiments.
Use appropriate git commit messages and branches to track the development progress.
Ensure that the repository is accessible to the instructor and teaching assistants.
4.2. Report (50%):
Write a comprehensive report describing your proposed solution, experiments, and findings.
The report should be in a format of your choice (e.g., PDF, Markdown, LaTeX) and can be written in any
preferred language.
4.3. Submission Deadline:
The GitHub repository link and the report should be submitted via Moodle by 2024.6.11.
Late submissions will be subject to the course's late submission policy.