A Framework for Conditional Diffusion Modelling with Applications in Motif Scaffolding for Protein Design

The proposed amortised training method can be applied to various domains beyond protein design by leveraging the framework based on Doob's h-transform. One potential application is in image generation tasks, where conditional diffusion models are used for tasks like image inpainting or style transfer. By conditioning the diffusion process on specific features or regions of an image, the model can generate realistic and high-quality images with desired attributes. Another domain where this method could be beneficial is natural language processing (NLP). Conditional diffusion models can be used for text generation tasks such as language translation, summarization, or dialogue generation. By conditioning the model on specific input sequences or target outputs, it can generate coherent and contextually relevant text. Furthermore, in reinforcement learning applications, amortised training of diffusion models could enhance policy learning and decision-making processes. By conditioning the model on different environmental states or reward signals, it can learn optimal policies for complex tasks in environments with high-dimensional state spaces. Overall, the flexibility and adaptability of the amortised training approach make it applicable to a wide range of domains beyond protein design, including computer vision, NLP, reinforcement learning, and more.

Implementing the unified framework based on Doob's h-transform in practical applications may pose certain challenges and limitations: Computational Complexity: The computational cost associated with training large-scale diffusion models using amortised methods might be significant due to increased parameter sizes and complexity. Data Requirements: Effective implementation requires a substantial amount of labeled data to train accurate noise predictors that capture complex relationships between variables accurately. Model Interpretability: Understanding how each component of the model contributes to its performance may become challenging as models grow more intricate. Hyperparameter Tuning: Optimizing hyperparameters for both neural networks involved in conditional sampling procedures might require extensive experimentation. Generalization Across Domains: Ensuring that the unified framework generalizes well across different application domains without sacrificing performance will also be crucial.

Utilizing Doob's h-transform enhances efficiency and accuracy in conditional diffusion modeling through several key mechanisms: Formal Conditioning Mechanism: Doob's h-transform provides a formal mechanism for conditioning stochastic differential equations (SDEs) to hit specific events at given times while maintaining theoretical rigor. Improved Sampling Accuracy: By incorporating hard equality constraints through Doob's transform drift term into SDEs during sampling processes ensures samples satisfy specified conditions within finite time frames accurately. Soft Constraint Handling: Generalized versions allow handling soft constraints effectively by providing a way to sample from noisy posteriors efficiently without relying solely on Gaussian approximations. 4 .Unified Framework Development: The unification under one common framework allows drawing connections between existing methods while proposing novel approaches like amortized training protocols leading to improved overall performance metrics across various applications such as motif scaffolding problems or image outpainting tasks.