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Main Authors: Proszewska, Magdalena, Malkin, Nikolay, Siddharth, N.
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2506.00136
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author Proszewska, Magdalena
Malkin, Nikolay
Siddharth, N.
author_facet Proszewska, Magdalena
Malkin, Nikolay
Siddharth, N.
contents Diffusion autoencoders (DAs) are variants of diffusion generative models that use an input-dependent latent variable to capture representations alongside the diffusion process. These representations, to varying extents, can be used for tasks such as downstream classification, controllable generation, and interpolation. However, the generative performance of DAs relies heavily on how well the latent variables can be modelled and subsequently sampled from. Better generative modelling is also the primary goal of another class of diffusion models -- those that learn their forward (noising) process. While effective at adjusting the noise process in an input-dependent manner, they must satisfy additional constraints derived from the terminal conditions of the diffusion process. Here, we draw a connection between these two classes of models and show that certain design decisions (latent variable choice, conditioning method, etc.) in the DA framework -- leading to a model we term DMZ -- allow us to obtain the best of both worlds: effective representations as evaluated on downstream tasks, including domain transfer, as well as more efficient modelling and generation with fewer denoising steps compared to standard DMs.
format Preprint
id arxiv_https___arxiv_org_abs_2506_00136
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle On Designing Diffusion Autoencoders for Efficient Generation and Representation Learning
Proszewska, Magdalena
Malkin, Nikolay
Siddharth, N.
Machine Learning
Diffusion autoencoders (DAs) are variants of diffusion generative models that use an input-dependent latent variable to capture representations alongside the diffusion process. These representations, to varying extents, can be used for tasks such as downstream classification, controllable generation, and interpolation. However, the generative performance of DAs relies heavily on how well the latent variables can be modelled and subsequently sampled from. Better generative modelling is also the primary goal of another class of diffusion models -- those that learn their forward (noising) process. While effective at adjusting the noise process in an input-dependent manner, they must satisfy additional constraints derived from the terminal conditions of the diffusion process. Here, we draw a connection between these two classes of models and show that certain design decisions (latent variable choice, conditioning method, etc.) in the DA framework -- leading to a model we term DMZ -- allow us to obtain the best of both worlds: effective representations as evaluated on downstream tasks, including domain transfer, as well as more efficient modelling and generation with fewer denoising steps compared to standard DMs.
title On Designing Diffusion Autoencoders for Efficient Generation and Representation Learning
topic Machine Learning
url https://arxiv.org/abs/2506.00136