Causal disentanglement of multimodal data

October 27, 2023 ยท Declared Dead ยท ๐Ÿ› Mathematical and Scientific Machine Learning - Providence, Rhode Island, United States of America - June - 2023

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Authors Elise Walker, Jonas A. Actor, Carianne Martinez, Nathaniel Trask arXiv ID 2310.18471 Category cs.LG: Machine Learning Cross-listed cs.AI, stat.ML Citations 2 Venue Mathematical and Scientific Machine Learning - Providence, Rhode Island, United States of America - June - 2023 Last Checked 4 months ago
Abstract
Causal representation learning algorithms discover lower-dimensional representations of data that admit a decipherable interpretation of cause and effect; as achieving such interpretable representations is challenging, many causal learning algorithms utilize elements indicating prior information, such as (linear) structural causal models, interventional data, or weak supervision. Unfortunately, in exploratory causal representation learning, such elements and prior information may not be available or warranted. Alternatively, scientific datasets often have multiple modalities or physics-based constraints, and the use of such scientific, multimodal data has been shown to improve disentanglement in fully unsupervised settings. Consequently, we introduce a causal representation learning algorithm (causalPIMA) that can use multimodal data and known physics to discover important features with causal relationships. Our innovative algorithm utilizes a new differentiable parametrization to learn a directed acyclic graph (DAG) together with a latent space of a variational autoencoder in an end-to-end differentiable framework via a single, tractable evidence lower bound loss function. We place a Gaussian mixture prior on the latent space and identify each of the mixtures with an outcome of the DAG nodes; this novel identification enables feature discovery with causal relationships. Tested against a synthetic and a scientific dataset, our results demonstrate the capability of learning an interpretable causal structure while simultaneously discovering key features in a fully unsupervised setting.
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