Deep active inference and scene construction
Deep active inference and scene construction
Adaptive agents must act in intrinsically uncertain environments with complex latent structure. Here, we elaborate a model of visual foraging—in a hierarchical context—wherein agents infer a higher-order visual pattern (a “scene”) by sequentially sampling ambiguous cues. Inspired by previous models of scene construction—that cast perception and action as consequences of approximate Bayesian inference—we use active inference to simulate decisions of agents categorizing a scene in a hierarchically-structured setting. Under active inference, agents develop probabilistic beliefs about their environment, while actively sampling it to maximize the evidence for their internal generative model. This approximate evidence maximization (i.e., self-evidencing) comprises drives to both maximize rewards and resolve uncertainty about hidden states. This is realized via minimization of a free energy functional of posterior beliefs about both the world as well as the actions used to sample or perturb it, corresponding to perception and action, respectively. We show that active inference, in the context of hierarchical scene construction, gives rise to many empirical evidence accumulation phenomena, such as noise-sensitive reaction times and epistemic saccades. We explain these behaviors in terms of the principled drives that constitute the expected free energy, the key quantity for evaluating policies under active inference. In addition, we report novel behaviors exhibited by these active inference agents that furnish new predictions for research on evidence accumulation and perceptual decision-making. We discuss the implications of this hierarchical active inference scheme for tasks that require planned sequences of information-gathering actions to infer compositional latent structure (such as visual scene construction and sentence comprehension). This work sets the stage for future experiments to investigate active inference in relation to other formulations of evidence accumulation (e.g., drift-diffusion models) in tasks that require planning in uncertain environments with higher-order structure.
Heins, R. Conor
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Mirza, M. Berk
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Parr, Thomas
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Friston, Karl
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Kagan, Igor
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Pooresmaeili, Arezoo
319b6aed-8454-4ad2-b16e-8fadfdfd2e53
28 October 2020
Heins, R. Conor
bedb7623-3ea7-4ba8-9e20-83e776028b3a
Mirza, M. Berk
34b54799-ab46-46da-bf4c-3e2f4f6d2a01
Parr, Thomas
6b28c712-3b8a-4453-b973-e0234a2796d5
Friston, Karl
1d2456b3-218e-4631-9e6b-8a9d97bb3441
Kagan, Igor
90c54335-e46b-47af-abe3-268c90f88276
Pooresmaeili, Arezoo
319b6aed-8454-4ad2-b16e-8fadfdfd2e53
Heins, R. Conor, Mirza, M. Berk, Parr, Thomas, Friston, Karl, Kagan, Igor and Pooresmaeili, Arezoo
(2020)
Deep active inference and scene construction.
Frontiers in Artificial Intelligence, 3.
(doi:10.3389/frai.2020.509354).
Abstract
Adaptive agents must act in intrinsically uncertain environments with complex latent structure. Here, we elaborate a model of visual foraging—in a hierarchical context—wherein agents infer a higher-order visual pattern (a “scene”) by sequentially sampling ambiguous cues. Inspired by previous models of scene construction—that cast perception and action as consequences of approximate Bayesian inference—we use active inference to simulate decisions of agents categorizing a scene in a hierarchically-structured setting. Under active inference, agents develop probabilistic beliefs about their environment, while actively sampling it to maximize the evidence for their internal generative model. This approximate evidence maximization (i.e., self-evidencing) comprises drives to both maximize rewards and resolve uncertainty about hidden states. This is realized via minimization of a free energy functional of posterior beliefs about both the world as well as the actions used to sample or perturb it, corresponding to perception and action, respectively. We show that active inference, in the context of hierarchical scene construction, gives rise to many empirical evidence accumulation phenomena, such as noise-sensitive reaction times and epistemic saccades. We explain these behaviors in terms of the principled drives that constitute the expected free energy, the key quantity for evaluating policies under active inference. In addition, we report novel behaviors exhibited by these active inference agents that furnish new predictions for research on evidence accumulation and perceptual decision-making. We discuss the implications of this hierarchical active inference scheme for tasks that require planned sequences of information-gathering actions to infer compositional latent structure (such as visual scene construction and sentence comprehension). This work sets the stage for future experiments to investigate active inference in relation to other formulations of evidence accumulation (e.g., drift-diffusion models) in tasks that require planning in uncertain environments with higher-order structure.
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frai-03-509354
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Accepted/In Press date: 10 September 2020
Published date: 28 October 2020
Identifiers
Local EPrints ID: 481613
URI: http://eprints.soton.ac.uk/id/eprint/481613
ISSN: 2624-8212
PURE UUID: edb80ea8-6bce-41a5-9786-bc7fe0584ee8
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Date deposited: 05 Sep 2023 16:33
Last modified: 17 Mar 2024 04:18
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Contributors
Author:
R. Conor Heins
Author:
M. Berk Mirza
Author:
Thomas Parr
Author:
Karl Friston
Author:
Igor Kagan
Author:
Arezoo Pooresmaeili
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