We report experimentally on VCSEL-based artificial optical spiking neurons with ultrafast spiking refractory period; hence allowing operation at GHz rates. This feature is used to demonstrate all-optical digital-to-spiking information format conversion at 1.0 Gbps
We report both experimentally and in theory on the detection of edge features in digital images with...
Electrically-controlled, tuneable and repeatable neuron-like spiking regimes are generated in an opt...
Biological retinal neuronal circuits are emulated using a system of connected 1550 nm Vertical-Cavit...
We report experimentally on VCSEL-based artificial optical spiking neurons with ultrafast spiking re...
Driven by the increasing significance of artificial intelligence, the field of neuromorphic (brain-i...
With the increasing importance and capabilities of artificial intelligence (AI) approaches across al...
In this thesis we investigate the technology of Vertical Cavity Surface Emitting Lasers (VCSELs) as ...
Vertical-Cavity Surface-Emitting Lasers (VCSELs) are highly promising devices for the construction o...
The ever-increasing demand for artificial intelligence (AI) systems is underlining a significant req...
In today’s data-driven world, the ability to process large data volumes is crucial. Key tasks, such ...
We report on the activation, inhibition and propagation of controllable neuron-like spiking signals ...
We report experimentally on the electrically-controlled, tunable and repeatable neuron-like spiking ...
Photonic technologies offer great prospects for novel, ultrafast, energy-efficient, and hardwarefrie...
Biological retinal neuronal circuits are emulated using a system of connected 1550 nm Vertical-Cavit...
We report experimentally and in theory on the controllable propagation of spiking regimes between tw...
We report both experimentally and in theory on the detection of edge features in digital images with...
Electrically-controlled, tuneable and repeatable neuron-like spiking regimes are generated in an opt...
Biological retinal neuronal circuits are emulated using a system of connected 1550 nm Vertical-Cavit...
We report experimentally on VCSEL-based artificial optical spiking neurons with ultrafast spiking re...
Driven by the increasing significance of artificial intelligence, the field of neuromorphic (brain-i...
With the increasing importance and capabilities of artificial intelligence (AI) approaches across al...
In this thesis we investigate the technology of Vertical Cavity Surface Emitting Lasers (VCSELs) as ...
Vertical-Cavity Surface-Emitting Lasers (VCSELs) are highly promising devices for the construction o...
The ever-increasing demand for artificial intelligence (AI) systems is underlining a significant req...
In today’s data-driven world, the ability to process large data volumes is crucial. Key tasks, such ...
We report on the activation, inhibition and propagation of controllable neuron-like spiking signals ...
We report experimentally on the electrically-controlled, tunable and repeatable neuron-like spiking ...
Photonic technologies offer great prospects for novel, ultrafast, energy-efficient, and hardwarefrie...
Biological retinal neuronal circuits are emulated using a system of connected 1550 nm Vertical-Cavit...
We report experimentally and in theory on the controllable propagation of spiking regimes between tw...
We report both experimentally and in theory on the detection of edge features in digital images with...
Electrically-controlled, tuneable and repeatable neuron-like spiking regimes are generated in an opt...
Biological retinal neuronal circuits are emulated using a system of connected 1550 nm Vertical-Cavit...