Optoelectronic spiking neurons are regarded as highly promising systems for novel light-powered neuromorphic computing hardware. Here, we investigate an optoelectronic (O/E/O) spiking neuron built with an excitable resonant tunnelling diode (RTD) coupled to a photodetector and a vertical-cavity surface-emitting laser (VCSEL). This work provides the first experimental report on the control of the amplitude (weighting factor) of the fired optical spikes directly in the neuron, introducing a simple way for presynaptic spike amplitude tuning. Notably, a very simple mechanism (the control of VCSEL bias) is used to tune the amplitude of the spikes fired by the optoelectronic neuron, hence enabling an easy and high-speed option for the weighting o...
With the increasing importance and capabilities of artificial intelligence (AI) approaches across al...
We report experimentally on VCSEL-based artificial optical spiking neurons with ultrafast spiking re...
Biological retinal neuronal circuits are emulated using a system of connected 1550 nm Vertical-Cavit...
Optoelectronic spiking neurons are regarded as highly promising systems for novel light-powered neur...
Excitable optoelectronic devices represent one of the key building blocks for implementation of arti...
We report experimentally on the electrically-controlled, tunable and repeatable neuron-like spiking ...
In this thesis we investigate the technology of Vertical Cavity Surface Emitting Lasers (VCSELs) as ...
Driven by the increasing significance of artificial intelligence, the field of neuromorphic (brain-i...
Electrically-controlled, tuneable and repeatable neuron-like spiking regimes are generated in an opt...
In this work, we introduce an interconnected nano-optoelectronic spiking artificial neuron emitter-r...
We report high-speed, energy-efficient artificial optoelectronic spiking neurons based upon resonant...
Vertical-Cavity Surface-Emitting Lasers (VCSELs) are highly promising devices for the construction o...
Photonic approaches emulating the powerful computational capabilities of the brain are receiving inc...
With the recent development of artificial intelligence and deep neural networks, alternatives to the...
Photonic technologies offer great prospects for novel, ultrafast, energy-efficient, and hardwarefrie...
With the increasing importance and capabilities of artificial intelligence (AI) approaches across al...
We report experimentally on VCSEL-based artificial optical spiking neurons with ultrafast spiking re...
Biological retinal neuronal circuits are emulated using a system of connected 1550 nm Vertical-Cavit...
Optoelectronic spiking neurons are regarded as highly promising systems for novel light-powered neur...
Excitable optoelectronic devices represent one of the key building blocks for implementation of arti...
We report experimentally on the electrically-controlled, tunable and repeatable neuron-like spiking ...
In this thesis we investigate the technology of Vertical Cavity Surface Emitting Lasers (VCSELs) as ...
Driven by the increasing significance of artificial intelligence, the field of neuromorphic (brain-i...
Electrically-controlled, tuneable and repeatable neuron-like spiking regimes are generated in an opt...
In this work, we introduce an interconnected nano-optoelectronic spiking artificial neuron emitter-r...
We report high-speed, energy-efficient artificial optoelectronic spiking neurons based upon resonant...
Vertical-Cavity Surface-Emitting Lasers (VCSELs) are highly promising devices for the construction o...
Photonic approaches emulating the powerful computational capabilities of the brain are receiving inc...
With the recent development of artificial intelligence and deep neural networks, alternatives to the...
Photonic technologies offer great prospects for novel, ultrafast, energy-efficient, and hardwarefrie...
With the increasing importance and capabilities of artificial intelligence (AI) approaches across al...
We report experimentally on VCSEL-based artificial optical spiking neurons with ultrafast spiking re...
Biological retinal neuronal circuits are emulated using a system of connected 1550 nm Vertical-Cavit...