Decision making and perceptual bistability in spike-based neuromorphic VLSI systems

Corradi, Federico; You, Hongzhi; Giulioni, Massimiliano; Indiveri, Giacomo

doi:10.1109/iscas.2015.7169245

Cited by 17 publications

(12 citation statements)

References 20 publications

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“…As mentioned in the introduction section, several neuromorphic circuits and hardware related to the CANN have been proposed. Regarding functionality, Corradi and his collaborators implemented decision making and perceptual bistability in a neuromorphic VLSI chip [53]. However, slow ramp-up activities, which are critical for evidence accumula-tion during decision tasks, cannot be reproduced due to a lack of various synaptic dynamics, especially slow and nonlinear synapses.…”

Section: Conclusion and Discussionmentioning

confidence: 99%

Neuromorphic Implementation of a Continuous Attractor Neural Network With Various Synaptic Dynamics

You

Zhao

2021

IEEE Access

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A continuous attractor neural network (CANN) configured with various synaptic dynamics can implement many brain cognitive functions. Corresponding neuromorphic implementation can be beneficial to carry out these cognitive computations in real-time. Herein, we present a neuromorphic implementation of the CANN of spiking neurons on the field-programmable gate array (FPGA), in which the synaptic strength of local excitation and global inhibition can be configured to achieve winner-takeall (WTA) competition. In contrast to previously reported neuromorphic CANN, in addition to fast-linear synapses, recurrent connections can also be implemented with slow-nonlinear synapses. This endows the proposed CANN on the FPGA with the capability of performing neural computations that require slow and nonlinear temporal dynamics, such as decision making and working memory. Circuit simulations on the hardware reproduced gradually ramping neural activities observed in decision-making experiments and multiple sustained activities observed during the delay in working memory experiments, especially the fade-out and merging of activity bumps in the latter task. Theoretical analysis illuminated the underlying mechanisms of decision making and working memory on the FPGA. The unstable two-bump steady state of the CANN is responsible for the two-alternative decision making, similar to the saddle-node structure in the reduced two-variable decision model. Meanwhile, the stable uniformly distributed N-bump steady states account for the multiple-item working memory, similar to the multistability in previous mean-field models. Furthermore, the asymmetrical N-bump unstable steady states exhibit attractor dynamics underlying the fade-out and merging of activity bumps. The consistency between simulations on the hardware and the theoretical analysis demonstrated that the neuromorphic CANN is endowed with attractor dynamics relating to slow and nonlinear neural computations and has the potential to implement sophisticated cognitive functions by configuring various synaptic dynamics. This implementation shows promise for integrating the cognitive platform due to its characteristics of various dynamics and flexible configurations.INDEX TERMS neuromorphic engineering, continuous attractor neural network, attractor dynamics, decision making, working memory

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Section: Conclusion and Discussionmentioning

confidence: 99%

Neuromorphic Implementation of a Continuous Attractor Neural Network With Various Synaptic Dynamics

You

Zhao

2021

IEEE Access

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“…However, the specific network architecture through which neurons perceive the conflicts and reach the maximum consistency solution is still unknown. Several software and hardware models have been proposed to explain how the conflicts are avoided and how the stable state is approached, using attractor dynamics and competitive Winner-Take-All (WTA) networks [6], [7], [8], [9], [10], [11], [12], [13]. However, most of these models are based on the assumption that the network can get out of local minima thanks to external stochastic stimuli or injected noise currents.…”

Section: Introductionmentioning

confidence: 99%

A Neuromorphic Computational Primitive for Robust Context-Dependent Decision Making and Context-Dependent Stochastic Computation

Liang

Indiveri

2019

IEEE Trans. Circuits Syst. II

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The prefrontal cortex (PFC) plays an important role in complex cognitive computations, including planning and decision making. Although recurrent spiking neural network (SNN) software models of PFC have been successful in reproducing many of its cognitive computational aspects, little attention has been devoted to the question of how such systems can perform with low-resolution parameters and be robust to noise and variability in their input signals and state variables. Here, we present a mixed-signal analog/digital neuromorphic implementation of a state-dependent SNN architecture that addresses these issues by construction. The network relies on synaptic dis-inhibition to ensure robust decision making even in the face of very large variability. Depending on its connectivity, the network can either perform robustly in a deterministic way or exploit the device mismatch and noise to explore stochastically multiple states in constraint satisfaction problems (CSPs). We validate the architecture by mapping it onto a network of spiking neurons in a multi-core mixed-signal neuromorphic system and presenting experimental results for three different examples of CSPs.

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“…These chips effectively model neurons and synapses in a compact architecture that consumes orders of magnitude less power than a comparable digital system [1], [2]. Most synthetic neural research has been focused around pattern recognition, image processing, or decision making [3]- [5]. Almost all of these systems do not require quick reactions to external changes or interaction with an unpredictable environment.…”

Section: Introductionmentioning

confidence: 99%

A Dynamic Neural Network Designed Using Analytical Methods Produces Dynamic Control Properties Similar to an Analogous Classical Controller

Hilts

Szczecinski

Quinn

et al. 2019

IEEE Control Syst. Lett.

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Decision making and perceptual bistability in spike-based neuromorphic VLSI systems

Cited by 17 publications

References 20 publications

Neuromorphic Implementation of a Continuous Attractor Neural Network With Various Synaptic Dynamics

Neuromorphic Implementation of a Continuous Attractor Neural Network With Various Synaptic Dynamics

A Neuromorphic Computational Primitive for Robust Context-Dependent Decision Making and Context-Dependent Stochastic Computation

A Dynamic Neural Network Designed Using Analytical Methods Produces Dynamic Control Properties Similar to an Analogous Classical Controller

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