Iterative free-energy optimization for recurrent neural networks (INFERNO)

Pitti, Alexandre; Gaussier, Philippe; Quoy, Mathias

doi:10.1371/journal.pone.0173684

Cited by 12 publications

(35 citation statements)

References 95 publications

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“…We showed in [1] that this variational process is similar to a stochastic descent gradient algorithm performed iteratively. We here add a more sophisticated gradient descent algorithm corresponding to a simulated annealing mechanism in order to account for the neuromodulators involved in decision-making in the PFC for uncertainty and surprise [16,95].…”

Section: The Network Architecture Inferno Gatementioning

confidence: 99%

“…In this paper, we propose to use the neural architecture Inferno, standing for Iterative Free-Energy Optimization in Recurrent Neural Network, for the learning of temporal patterns and the serial recall of sequences [1,2]. We originally proposed this neuronal architecture to model the cortico-basal ganglia loop [1] for retrieving motor and audio primitives using Spike Timing-dependent Plasticity (STDP) within the framework of predictive coding and free-energy minimization [3,4,5]. Here, we propose to implement a similar free-energy minimization network but this time in the prefrontal-basal ganglia loop for the serial recall of memory sequences and for the learning of temporal pattern primitives, using gain-modulation instead of STDP.…”

Section: Proposal Framework For Sequence Learningmentioning

confidence: 99%

“…The neural architecture Inferno Gate reproduces the main configuration of the original Inferno network [1] with two coupled learning systems that minimize their mutual prediction error (the free-energy), see In order to minimize error, the second network (dlPFC/OFC) generates intrinsic noise I noise to control the dynamics of the first one (lPFC/dlPFC) following a reinforcement learning (RL) mechanism. In Fig.…”

Section: The Network Architecture Inferno Gatementioning

confidence: 99%

“…The rank-order coding (ROC) algorithm has been proposed by Thorpe and colleagues to model the information processing performed in the Visual Cortex by feedforward integrate-and-fire neurons [96]. We have expanded their use to recurrent neural network models in [97,1] replicating the Spike Timing-Dependent Plasticity learning mechanism.…”

Section: Gain-modulation Mechanism Based On Rank-order Codingmentioning

confidence: 99%

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Gated spiking neural network using Iterative Free-Energy Optimization and rank-order coding for structure learning in memory sequences (INFERNO GATE)

et al. 2020

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We present a framework based on iterative free-energy optimization with spiking neural networks for modeling the fronto-striatal system (PFC-BG) for the generation and recall of audio memory sequences. In line with neuroimaging studies carried out in the PFC, we propose a genuine coding strategy using the gain-modulation mechanism to represent abstract sequences based solely on the rank and location of items within them. Based on this mechanism, we show that we can construct a repertoire of neurons sensitive to the temporal structure in sequences from which we can represent any novel sequences. Freeenergy optimization is then used to explore and to retrieve the missing indices of the items in the correct order for executive control and compositionality. We show that the gain-modulation mechanism permits the network to be robust to variabilities and to have long-term dependencies as it implements a gated recurrent neural network. This model, called Inferno Gate, is an extension of the neural architecture Inferno standing for Iterative Free-Energy Optimization of Recurrent Neural Networks with Gating or Gain-modulation. In experiments performed with an audio database of ten thousand MFCC vectors, Inferno Gate is capable of encoding efficiently and retrieving chunks of fifty items length. We

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Section: The Network Architecture Inferno Gatementioning

confidence: 99%

Section: Proposal Framework For Sequence Learningmentioning

confidence: 99%

Section: The Network Architecture Inferno Gatementioning

confidence: 99%

Section: Gain-modulation Mechanism Based On Rank-order Codingmentioning

confidence: 99%

See 2 more Smart Citations

Gated spiking neural network using Iterative Free-Energy Optimization and rank-order coding for structure learning in memory sequences (INFERNO GATE)

et al. 2020

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“…The minimization of the free energy means to predict for one particular policy its expected state and to optimize it over time in order to minimize future errors [4]. Our neural model is based on this principle of Iterative Free-Energy Optimization for Recurrent Neural Networks, and we named it INFERNO [9], see Fig. 1.…”

Section: Introductionmentioning

confidence: 99%

INFERNO: A Novel Architecture for Generating Long Neuronal Sequences with Spikes

Pitti

Gaussier

Quoy

2017

Advances in Neural Networks - ISNN 2017

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Abstract. Human working memory is capable to generate dynamically robust and flexible neuronal sequences for action planning, problem solving and decision making. However, current neurocomputational models of working memory find hard to achieve these capabilities since intrinsic noise is difficult to stabilize over time and destroys global synchrony. As part of the principle of free-energy minimization proposed by Karl Friston, we propose a novel neural architecture to optimize the free-energy inherent to spiking recurrent neural networks to regulate their activity. We show for the first time that it is possible to stabilize iteratively the long-range control of a recurrent spiking neurons network over long sequences. We identify our architecture as the working memory composed by the Basal Ganglia and the Intra-Parietal Lobe for action selection and we make some comparisons with other networks such as deep neural networks and neural Turing machines. We name our architecture INFERNO for Iterative Free-Energy Optimization for Recurrent Neural Network. abstract environment.

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Learning, planning, and control in a monolithic neural event inference architecture

et al. 2019

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We introduce REPRISE, a REtrospective and PRospective Inference SchEme, which learns temporal event-predictive models of dynamical systems. REPRISE infers the unobservable contextual event state and accompanying temporal predictive models that best explain the recently encountered sensorimotor experiences retrospectively. Meanwhile, it optimizes upcoming motor activities prospectively in a goal-directed manner. Here, REPRISE is implemented by a recurrent neural network (RNN), which learns temporal forward models of the sensorimotor contingencies generated by different simulated dynamic vehicles. The RNN is augmented with contextual neurons, which enable the encoding of distinct, but related, sensorimotor dynamics as compact event codes. We show that REPRISE concurrently learns to separate and approximate the encountered sensorimotor dynamics: it analyzes sensorimotor error signals adapting both internal contextual neural activities and connection weight values. Moreover, we show that REPRISE can exploit the learned model to induce goal-directed, model-predictive control, that is, approximate active inference: Given a goal state, the system imagines a motor command sequence optimizing it with the prospective objective to minimize the distance to the goal. The RNN activities thus continuously imagine the upcoming future and reflect on the recent past, optimizing the predictive model, the hidden neural state activities, and the upcoming motor activities. As a result, event-predictive neural encodings develop, which allow the invocation of highly effective and adaptive goal-directed sensorimotor control.

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Iterative free-energy optimization for recurrent neural networks (INFERNO)

Cited by 12 publications

References 95 publications

Gated spiking neural network using Iterative Free-Energy Optimization and rank-order coding for structure learning in memory sequences (INFERNO GATE)

Gated spiking neural network using Iterative Free-Energy Optimization and rank-order coding for structure learning in memory sequences (INFERNO GATE)

INFERNO: A Novel Architecture for Generating Long Neuronal Sequences with Spikes

Learning, planning, and control in a monolithic neural event inference architecture

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