Animal nervous systems are highly efficient in processing sensory input. The neuromorphic computing paradigm aims at the hardware implementation of neural network computations to support novel solutions for building brain-inspired computing systems. Here, we take inspiration from sensory processing in the nervous system of the fruit fly larva. With its strongly limited computational resources of <200 neurons and <1.000 synapses the larval olfactory pathway employs fundamental computations to transform broadly tuned receptor input at the periphery into an energy efficient sparse code in the central brain. We show how this approach allows us to achieve sparse coding and increased separability of stimulus patterns in a spiking neural net...
Michael Schmuker, Thomas Pfeil, and Martin Paul Nawrot, ‘A neuromorphic network for generic multivar...
"Sparse" neural networks, in which relatively few neurons or connections are active, are common in b...
Understanding the operating principles of the brain functions is the key to building novel computing...
Animal nervous systems are highly efficient in processing sensory input. The neuromorphic computing ...
Sparse neural coding provides numerous computational advantages. A recent analysis of the locust olf...
SummaryUnderstanding adaptive phenotypic change and its genetic underpinnings is a major challenge i...
In the mushroom body of insects, odors are represented by very few spikes in a small number of neuro...
The neural representation of a stimulus is repeatedly transformed as it moves from the sensory perip...
SummaryIn several sensory pathways, input stimuli project to sparsely active downstream populations ...
Sparse coding may be a general strategy of neural systems for augmenting memory capacity. In Drosoph...
Olfactory stimuli are represented in a highdimensional space by neural networks of the olfactory sys...
The mushroom body is the key network for the representation of learned olfactory stimuli in Drosophi...
abstract: Olfaction is an important sensory modality for behavior since odors inform animals of the ...
Recent studies, using unbiased sampling of neuronal activity in vivo, indicate the existence of spar...
We present a biologically-constrained neuromorphic spiking model of the insect antennal lobe macrogl...
Michael Schmuker, Thomas Pfeil, and Martin Paul Nawrot, ‘A neuromorphic network for generic multivar...
"Sparse" neural networks, in which relatively few neurons or connections are active, are common in b...
Understanding the operating principles of the brain functions is the key to building novel computing...
Animal nervous systems are highly efficient in processing sensory input. The neuromorphic computing ...
Sparse neural coding provides numerous computational advantages. A recent analysis of the locust olf...
SummaryUnderstanding adaptive phenotypic change and its genetic underpinnings is a major challenge i...
In the mushroom body of insects, odors are represented by very few spikes in a small number of neuro...
The neural representation of a stimulus is repeatedly transformed as it moves from the sensory perip...
SummaryIn several sensory pathways, input stimuli project to sparsely active downstream populations ...
Sparse coding may be a general strategy of neural systems for augmenting memory capacity. In Drosoph...
Olfactory stimuli are represented in a highdimensional space by neural networks of the olfactory sys...
The mushroom body is the key network for the representation of learned olfactory stimuli in Drosophi...
abstract: Olfaction is an important sensory modality for behavior since odors inform animals of the ...
Recent studies, using unbiased sampling of neuronal activity in vivo, indicate the existence of spar...
We present a biologically-constrained neuromorphic spiking model of the insect antennal lobe macrogl...
Michael Schmuker, Thomas Pfeil, and Martin Paul Nawrot, ‘A neuromorphic network for generic multivar...
"Sparse" neural networks, in which relatively few neurons or connections are active, are common in b...
Understanding the operating principles of the brain functions is the key to building novel computing...