With the remarkable progress that technology has made, the need for processing data near the sensors at the edge has increased dramatically. The electronic systems used in these applications must process data continuously, in real-time, and extract relevant information using the smallest possible energy budgets. A promising approach for implementing always-on processing of sensory signals that supports on-demand, sparse, and edge-computing is to take inspiration from biological nervous system. Following this approach, we present a brain-inspired platform for prototyping real-time event-based Spiking Neural Networks (SNNs). The system proposed supports the direct emulation of dynamic and realistic neural processing phenomena such as short-te...
In this work we model and implement detailed and large- scale neural and synaptic dynamics in silico...
Reproducing the dynamics of biological neural systems using mixed signal analog/digital neuromorphic...
Abstract—We implement a digital neuron in silicon using delay-insensitive asynchronous circuits. Our...
With the remarkable progress that technology has made, the need for processing data near the sensors...
Mixed-signal neuromorphic processors have brain-like organization and device physics optimized for e...
A spiking-neuron-based system that combines analog and digital multi-processor implementations for t...
Over the past three decades, the field of neuromorphic engineering has produced sensors and processo...
Inference of Deep Neural Networks for stream signal (Video/Audio) processing in edge devices is stil...
The aim of this research is to develop a simple and effective continuous-time Spiking Neural Network...
Spiking neural networks have shown great promise for the design of low-power sensory-processing and ...
Artificial intelligence (AI) has the potential to transform people’s lives. While recent successes i...
Mixed-signal neuromorphic processors emulate the electrochemical dynamics of neurons and synapses us...
This dissertation is concerned with biologically inspired artificial neural networks, which offer sp...
Corneil D, Sonnleithner D, Neftci E, et al. Real-time inference in a VLSI spiking neural network. In...
In this work, we introduce an interconnected nano-optoelectronic spiking artificial neuron emitter-r...
In this work we model and implement detailed and large- scale neural and synaptic dynamics in silico...
Reproducing the dynamics of biological neural systems using mixed signal analog/digital neuromorphic...
Abstract—We implement a digital neuron in silicon using delay-insensitive asynchronous circuits. Our...
With the remarkable progress that technology has made, the need for processing data near the sensors...
Mixed-signal neuromorphic processors have brain-like organization and device physics optimized for e...
A spiking-neuron-based system that combines analog and digital multi-processor implementations for t...
Over the past three decades, the field of neuromorphic engineering has produced sensors and processo...
Inference of Deep Neural Networks for stream signal (Video/Audio) processing in edge devices is stil...
The aim of this research is to develop a simple and effective continuous-time Spiking Neural Network...
Spiking neural networks have shown great promise for the design of low-power sensory-processing and ...
Artificial intelligence (AI) has the potential to transform people’s lives. While recent successes i...
Mixed-signal neuromorphic processors emulate the electrochemical dynamics of neurons and synapses us...
This dissertation is concerned with biologically inspired artificial neural networks, which offer sp...
Corneil D, Sonnleithner D, Neftci E, et al. Real-time inference in a VLSI spiking neural network. In...
In this work, we introduce an interconnected nano-optoelectronic spiking artificial neuron emitter-r...
In this work we model and implement detailed and large- scale neural and synaptic dynamics in silico...
Reproducing the dynamics of biological neural systems using mixed signal analog/digital neuromorphic...
Abstract—We implement a digital neuron in silicon using delay-insensitive asynchronous circuits. Our...