Jamal Lottier Molin scite author profile

Neuromorphic engineering (NE) encompasses a diverse range of approaches to information processing that are inspired by neurobiological systems, and this feature distinguishes neuromorphic systems from conventional computing systems. The brain has evolved over billions of years to solve difficult engineering problems by using efficient, parallel, low-power computation. The goal of NE is to design systems capable of brain-like computation. Numerous large-scale neuromorphic projects have emerged recently. This interdisciplinary field was listed among the top 10 technology breakthroughs of 2014 by the MIT Technology Review and among the top 10 emerging technologies of 2015 by the World Economic Forum. NE has two-way goals: one, a scientific goal to understand the computational properties of biological neural systems by using models implemented in integrated circuits (ICs); second, an engineering goal to exploit the known properties of biological systems to design and implement efficient devices for engineering applications. Building hardware neural emulators can be extremely useful for simulating large-scale neural models to explain how intelligent behavior arises in the brain. The principal advantages of neuromorphic emulators are that they are highly energy efficient, parallel and distributed, and require a small silicon area. Thus, compared to conventional CPUs, these neuromorphic emulators are beneficial in many engineering applications such as for the porting of deep learning algorithms for various recognitions tasks. In this review article, we describe some of the most significant neuromorphic spiking emulators, compare the different architectures and approaches used by them, illustrate their advantages and drawbacks, and highlight the capabilities that each can deliver to neural modelers. This article focuses on the discussion of large-scale emulators and is a continuation of a previous review of various neural and synapse circuits (Indiveri et al., 2011). We also explore applications where these emulators have been used and discuss some of their promising future applications.

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How is motion integrated into a proto-object based visual saliency model?

Molin

Etienne‐Cummings

Niebur

2015

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Corrigendum: Large-Scale Neuromorphic Spiking Array Processors: A Quest to Mimic the Brain

et al. 2019

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FPGA implementation of a Deep Belief Network architecture for character recognition using stochastic computation

Sanni

Garreau

Molin

et al. 2015

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Deep Neural Networks (DNNs) have proven very effec tive for classification and generative tasks, and are widely adapted in a variety of fields including vision, robotics, speech processing, and more. Specifically, Deep Belief Networks (DBNs), are graphical model constructed of multiple layers of nodes connected as Markov random fields, have been successfully implemented for tackling such tasks. However, because of the numerous connections between nodes in the networks, DBNs suffer a drawback of being computational intensive. In this work, we exploit an alternative approach based on computation on probabilistic unary streams for designing a more efficient deep neural network architecture for classification.

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Low-power, low-mismatch, highly-dense array of VLSI Mihalas-Niebur neurons

Molin

Eisape

Thakur

et al. 2017

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