A 0.086-mm&lt;formula&gt;
                     &lt;tex&gt;$^2$&lt;/tex&gt;
                  &lt;/formula&gt; 12.7-pJ/SOP 64k-Synapse 256-Neuron Online-Learning Digital Spiking Neuromorphic Processor in 28nm CMOS

Frenkel, Charlotte; Lefebvre, Martin; Legat, Jean-Didier; Bol, David

doi:10.1109/tbcas.2018.2880425

Cited by 189 publications

(172 citation statements)

References 70 publications

(127 reference statements)

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“…This rule is also competitive among the state-of-the-art spike-based machine learning methods. 1,10,43 According to this rule, every time the post-synaptic neuron emits a spike, an internal variable Ca 2+ , which represents calcium concentration and is proportional to the neuron's recent spiking activity, is incremented by a value J c and then decays with a time constant Ca , according to the dynamics of Equation (1),…”

Section: The Spike-driven Synaptic Plasticity Rulementioning

confidence: 99%

“…1,7,8 Several research groups around the world are developing custom hardware systems for simulating large-scale neural models. 1,9,10 So far, these systems have limitations in applications that require accurate calculations. For instance, simulating networks with reinforcement learning capabilities 11 or convolutional spiking neural networks for pattern recognition rely on precise values of weights.…”

Section: Introductionmentioning

confidence: 99%

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Digital multiplier‐less implementation of high‐precision SDSP and synaptic strength‐based STDP

Asgari

Maybodi

Sandamirskaya

2020

Circuit Theory & Apps

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Spiking neural networks (SNNs) can achieve lower latency and higher efficiency compared with traditional neural networks if they are implemented in dedicated neuromorphic hardware. In both biological and artificial spiking neuronal systems, synaptic modifications are the main mechanism for learning. Plastic synapses are thus the core component of neuromorphic hardware with on-chip learning capability. Recently, several research groups have designed hardware architectures for modeling plasticity in SNNs for various applications. Following these research efforts, this paper proposes multiplier-less digital neuromorphic circuits for two plasticity learning rules: the spike-driven synaptic plasticity (SDSP) and synaptic strength-based spike timing-dependent plasticity (SSSTDP). The proposed architectures have increased the precision of the plastic synaptic weights and are suitable for spiking neural network architectures with more precise calculations. The proposed models are validated in MATLAB simulations and physical implementations on a field-programmable gate array (FPGA). KEYWORDSFPGA, neuromorphic engineering, plastic synapse, spiking neural network (SNN) Int J Circ Theor Appl. 2020;48:724-738. wileyonlinelibrary.com/journal/cta

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Section: The Spike-driven Synaptic Plasticity Rulementioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Digital multiplier‐less implementation of high‐precision SDSP and synaptic strength‐based STDP

Asgari

Maybodi

Sandamirskaya

2020

Circuit Theory & Apps

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“…The mixed-signal neuron designs in BrainScaleS [20] and Neurogrid [3] offer the closest comparison to this work. TrueNorth [21], Loihi [22] and ODIN [23] are digital systems that use advanced processes, time-multiplexing of neurons and low supply voltages. They are also designed for high input and output data rates and are arguably less suited than the proposed neuron design for low-bandwidth sensor data processing applications.…”

Section: Comparison To Other Neuron Implementationsmentioning

confidence: 99%

An Ultra-Low Power Sigma-Delta Neuron Circuit

Nair

Indiveri

2019

2019 IEEE International Symposium on Circuits and Systems (ISCAS)

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Neural processing systems typically represent data using Leaky Integrate and Fire (LIF) neuron models that generate spikes or pulse trains at a rate proportional to their input amplitudes. This mechanism requires high firing rates when encoding time-varying signals, leading to increased power consumption. Neuromorphic systems that use adaptive LIF neuron models overcome this problem by encoding signals in the relative timing of their output spikes rather than their rate. In this paper, we analyze recent adaptive LIF neuron circuit implementations and highlight the analogies and differences between them and a first-order Σ∆ feedback loop. We propose a new Σ∆ neuron circuit that addresses some of the limitations in existing implementations and present simulation results that quantify the improvements. We show that the new circuit, implemented in a 1.8V , 180nm CMOS process, offers up to 42dB Signal to Distortion Ratio (SDR) and consumes orders of magnitude lower energy. Finally, we also demonstrate how the sigma-delta interpretation enables mapping of real-valued Recurrent Neural Networks (RNNs) to the spiking framework to emphasize the envisioned application of the proposed circuit.

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“…Communication of forward and backward propagated information is fully based on signed binary events, without the need to process floating point numbers, in contrast to the standard backpropagation algorithm [9]. This makes it particularly suitable for integration in digital neuromorphic platforms (such as [10]).…”

Section: Introductionmentioning

confidence: 99%

A Spiking Network for Inference of Relations Trained with Neuromorphic Backpropagation

Thiele

Bichler

Dupret

et al. 2019

2019 International Joint Conference on Neural Networks (IJCNN)

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The increasing need for intelligent sensors in a wide range of everyday objects requires the existence of low power information processing systems which can operate autonomously in their environment. In particular, merging and processing the outputs of different sensors efficiently is a necessary requirement for mobile agents with cognitive abilities. In this work, we present a multi-layer spiking neural network for inference of relations between stimuli patterns in dedicated neuromorphic systems. The system is trained with a new version of the backpropagation algorithm adapted to on-chip learning in neuromorphic hardware: Error gradients are encoded as spike signals which are propagated through symmetric synapses, using the same integrate-andfire hardware infrastructure as used during forward propagation. We demonstrate the strength of the approach on an arithmetic relation inference task and on visual XOR on the MNIST dataset. Compared to previous, biologically-inspired implementations of networks for learning and inference of relations, our approach is able to achieve better performance with less neurons. Our architecture is the first spiking neural network architecture with on-chip learning capabilities, which is able to perform relational inference on complex visual stimuli. These features make our system interesting for sensor fusion applications and embedded learning in autonomous neuromorphic agents.

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A 0.086-mm<formula> <tex>$^2$</tex> </formula> 12.7-pJ/SOP 64k-Synapse 256-Neuron Online-Learning Digital Spiking Neuromorphic Processor in 28nm CMOS

Cited by 189 publications

References 70 publications

Digital multiplier‐less implementation of high‐precision SDSP and synaptic strength‐based STDP

Digital multiplier‐less implementation of high‐precision SDSP and synaptic strength‐based STDP

An Ultra-Low Power Sigma-Delta Neuron Circuit

A Spiking Network for Inference of Relations Trained with Neuromorphic Backpropagation

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