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Main Authors: Saanum, Tankred, Buschoff, Luca M. Schulze, Dayan, Peter, Schulz, Eric
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2410.04940
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author Saanum, Tankred
Buschoff, Luca M. Schulze
Dayan, Peter
Schulz, Eric
author_facet Saanum, Tankred
Buschoff, Luca M. Schulze
Dayan, Peter
Schulz, Eric
contents Compositional representations are thought to enable humans to generalize across combinatorially vast state spaces. Models with learnable object slots, which encode information about objects in separate latent codes, have shown promise for this type of generalization but rely on strong architectural priors. Models with distributed representations, on the other hand, use overlapping, potentially entangled neural codes, and their ability to support compositional generalization remains underexplored. In this paper we examine whether distributed models can develop linearly separable representations of objects, like slotted models, through unsupervised training on videos of object interactions. We show that, surprisingly, models with distributed representations often match or outperform models with object slots in downstream prediction tasks. Furthermore, we find that linearly separable object representations can emerge without object-centric priors, with auxiliary objectives like next-state prediction playing a key role. Finally, we observe that distributed models' object representations are never fully disentangled, even if they are linearly separable: Multiple objects can be encoded through partially overlapping neural populations while still being highly separable with a linear classifier. We hypothesize that maintaining partially shared codes enables distributed models to better compress object dynamics, potentially enhancing generalization.
format Preprint
id arxiv_https___arxiv_org_abs_2410_04940
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Next state prediction gives rise to entangled, yet compositional representations of objects
Saanum, Tankred
Buschoff, Luca M. Schulze
Dayan, Peter
Schulz, Eric
Machine Learning
Computer Vision and Pattern Recognition
Compositional representations are thought to enable humans to generalize across combinatorially vast state spaces. Models with learnable object slots, which encode information about objects in separate latent codes, have shown promise for this type of generalization but rely on strong architectural priors. Models with distributed representations, on the other hand, use overlapping, potentially entangled neural codes, and their ability to support compositional generalization remains underexplored. In this paper we examine whether distributed models can develop linearly separable representations of objects, like slotted models, through unsupervised training on videos of object interactions. We show that, surprisingly, models with distributed representations often match or outperform models with object slots in downstream prediction tasks. Furthermore, we find that linearly separable object representations can emerge without object-centric priors, with auxiliary objectives like next-state prediction playing a key role. Finally, we observe that distributed models' object representations are never fully disentangled, even if they are linearly separable: Multiple objects can be encoded through partially overlapping neural populations while still being highly separable with a linear classifier. We hypothesize that maintaining partially shared codes enables distributed models to better compress object dynamics, potentially enhancing generalization.
title Next state prediction gives rise to entangled, yet compositional representations of objects
topic Machine Learning
Computer Vision and Pattern Recognition
url https://arxiv.org/abs/2410.04940