Longitudinal datasets measured repeatedly over time from individual subjects, arise in many biomedical, psychological, social, and other studies. A common approach to analyse high-dimensional data that contains missing values is to learn a low-dimensional representation using variational autoencoders (VAEs). However, standard VAEs assume that the learnt representations are i.i.d., and fail to capture the correlations between the data samples. We propose the Longitudinal VAE (L-VAE), that uses a multi-output additive Gaussian process (GP) prior to extend the VAE's capability to learn structured low-dimensional representations imposed by auxiliary covariate information, and derive a new KL divergence upper bound for such GPs. Our approach can...
Gaining insights into complex high-dimensional data is challenging and typically requires the use of...
Imaging modalities and clinical measurement, as well as their time progression can be seen as hetero...
Abstract Variational Autoencoder (VAE) has achieved promising success since its emergence. In recen...
International audienceDisease progression models are crucial to understanding degenerative diseases....
International audienceInterpretable modeling of heterogeneous data channels is essential in medical ...
We propose causal recurrent variational autoencoder (CR-VAE), a novel generative model that is able ...
International audienceInterpretable progression models for longitudinal neuroimaging data are crucia...
Dimensionality reduction approaches are commonly used for the deconvolution of high-dimensional meta...
International audienceIn this paper, we propose a generative statistical model to learn the spatiote...
International audienceThe problem of building disease progression models with longitudinal data has ...
Gaussian processes offer an attractive framework for predictive modeling from longitudinal data, \ie...
Understanding pathological mechanisms for heterogeneous brain disorders is a difficult challenge. No...
Variational auto-encoders (VAEs) are a powerful approach to unsupervised learning. They enable scala...
Gaining insights into complex high-dimensional data is challenging and typically requires the use of...
Imaging modalities and clinical measurement, as well as their time progression can be seen as hetero...
Abstract Variational Autoencoder (VAE) has achieved promising success since its emergence. In recen...
International audienceDisease progression models are crucial to understanding degenerative diseases....
International audienceInterpretable modeling of heterogeneous data channels is essential in medical ...
We propose causal recurrent variational autoencoder (CR-VAE), a novel generative model that is able ...
International audienceInterpretable progression models for longitudinal neuroimaging data are crucia...
Dimensionality reduction approaches are commonly used for the deconvolution of high-dimensional meta...
International audienceIn this paper, we propose a generative statistical model to learn the spatiote...
International audienceThe problem of building disease progression models with longitudinal data has ...
Gaussian processes offer an attractive framework for predictive modeling from longitudinal data, \ie...
Understanding pathological mechanisms for heterogeneous brain disorders is a difficult challenge. No...
Variational auto-encoders (VAEs) are a powerful approach to unsupervised learning. They enable scala...
Gaining insights into complex high-dimensional data is challenging and typically requires the use of...
Imaging modalities and clinical measurement, as well as their time progression can be seen as hetero...
Abstract Variational Autoencoder (VAE) has achieved promising success since its emergence. In recen...