Deep Predictive Learning in Neocortex and Pulvinar

O’Reilly, Randall C.; Russin, Jacob; Zolfaghar, Maryam; Rohrlich, John

doi:10.1162/jocn_a_01708

Cited by 29 publications

(27 citation statements)

References 204 publications

(392 reference statements)

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“…First, it relies only on the observation sequence (no supervision or reinforcement), leveraging prediction error signals, which have been found in the brain in many studies (Den Ouden et al, 2012;Eshel et al, 2013;Maheu et al, 2019). Importantly, in predictive coding (Rao & Ballard, 1999), the computation of prediction errors is part of the prediction process; here we are suggesting that it may also be part of the training process (as argued in (O'Reilly et al, 2021)). Second, relatively few iterations of training suffice (Fig.…”

Section: Training: Its Role and Possible Biological Counterpartmentioning

confidence: 51%

Gated recurrence enables simple and accurate sequence prediction in stochastic, changing, and structured environments

Foucault

Meyniel

2021

eLife

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From decision making to perception to language, predicting what is coming next is crucial. It is also challenging in stochastic, changing, and structured environments; yet the brain makes accurate predictions in many situations. What computational architecture could enable this feat? Bayesian inference makes optimal predictions but is prohibitively difficult to compute. Here, we show that a specific recurrent neural network architecture enables simple and accurate solutions in several environments. This architecture relies on three mechanisms: gating, lateral connections, and recurrent weight training. Like the optimal solution and the human brain, such networks develop internal representations of their changing environment (including estimates of the environment's latent variables and the precision of these estimates), leverage multiple levels of latent structure, and adapt their effective learning rate to changes without changing their connection weights. Being ubiquitous in the brain, gated recurrence could therefore serve as a generic building block to predict in real-life environments.

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Section: Training: Its Role and Possible Biological Counterpartmentioning

confidence: 51%

Gated recurrence enables simple and accurate sequence prediction in stochastic, changing, and structured environments

Foucault

Meyniel

2021

eLife

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“…Although this form of error-driven learning might make sense computationally, how could something like this delta error signal emerge naturally from the hippocampal biology? First, as in our prior model of learning in the monosynaptic pathway (Ketz et al, 2013), we adopt the idea that the delta arises as a temporal difference between two states of activity over the CA3, which is also consistent with a broader understanding of how error-driven learning works in the neocortex; (O'Reilly, 1996;O'Reilly & Munakata, 2000;O'Reilly, Russin, Zolfaghar, & Rohrlich, 2021). The appropriate temporal difference over CA3 should actually emerge naturally from the additional delay associated with the propagation of the MF signal through the DG to the CA3, compared to the more direct PP signal from ECin to CA3.…”

Section: Sources Of Error Driven Learning In the Hippocampal Circuitmentioning

confidence: 99%

Correcting the Hebbian Mistake: Toward a Fully Error-Driven Hippocampus

Zheng

Liu

Nishiyama

et al. 2021

Preprint

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The hippocampus plays a critical role in the rapid learning of new episodic memories. Many computational models propose that the hippocampus is an autoassociator that relies on Hebbian learning (i.e., “cells that fire together, wire together”). However, Hebbian learning is computationally suboptimal as it modifies weights unnecessarily beyond what is actually needed to achieve effective retrieval, causing more interference and resulting in a lower learning capacity. Our previous computational models have utilized a powerful, biologically plausible form of error-driven learning in hippocampal CA1 and entorhinal cortex (EC) (functioning as a sparse autoencoder) by contrasting local activity states at different phases in the theta cycle. Based on specific neural data and a recent abstract computational model, we propose a new model called Theremin (Total Hippocampal ERror MINimization) that extends error-driven learning to area CA3 — the mnemonic heart of the hippocampal system. In the model, CA3 responds to the EC monosynaptic input prior to the EC disynaptic input through dentate gyrus (DG), giving rise to a temporal difference between these two activation states, which drives error-driven learning in the EC→CA3 and CA3↔CA3 projections. In effect, DG serves as a teacher to CA3, correcting its patterns into more pattern-separated ones, thereby reducing interference. Results showed that Theremin, compared with our original model, has significantly increased capacity and learning speed. The model makes several novel predictions that can be tested in future studies.

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“…Importantly, in predictive coding 65 , the computation of prediction errors is part of the prediction process; here we are suggesting that it may also be part of the training process (as argued in Ref. 119 ). The second aspect is that relatively few iterations of training suffice (Supplementary Fig.…”

Section: Weight Tuning: Its Role and Possible Biological Counterpartmentioning

confidence: 52%

Gated recurrence enables simple and accurate sequence prediction in stochastic, changing, and structured environments

Foucault

Meyniel

2021

Preprint

View full text Add to dashboard Cite

From decision making to perception to language, predicting what is coming next is crucial. It is also challenging in stochastic, changing, and structured environments; yet the brain makes accurate predictions in many situations. What computational architecture could enable this feat? Bayesian inference makes optimal predictions but is prohibitively difficult to compute. Here, we show that a specific recurrent neural network architecture enables simple and accurate solutions in several environments. To this end, a set of three mechanisms suffices: gating, lateral connections, and recurrent weight tuning. Like the human brain, such networks develop internal representations of their changing environment (including estimates of the environment's latent variables and the precision of these estimates), leverage multiple levels of latent structure, and adapt their effective learning rate to changes without changing their connection weights. Being ubiquitous in the brain, gated recurrence could therefore serve as a generic building block to predict in real-life environments.

show abstract

Deep Predictive Learning in Neocortex and Pulvinar

Cited by 29 publications

References 204 publications

Gated recurrence enables simple and accurate sequence prediction in stochastic, changing, and structured environments

Gated recurrence enables simple and accurate sequence prediction in stochastic, changing, and structured environments

Correcting the Hebbian Mistake: Toward a Fully Error-Driven Hippocampus

Gated recurrence enables simple and accurate sequence prediction in stochastic, changing, and structured environments

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