This article highlights specific features of biological neurons and their dendritic trees, whose adoption may help advance artificial neural networks used in various machine learning applications. Advancements could take the form of increased computational capabilities and/or reduced power consumption. Proposed features include dendritic anatomy, dendritic nonlinearities, and compartmentalized plasticity rules, all of which shape learning and information processing in biological networks. We discuss the computational benefits provided by these features in biological neurons and suggest ways to adapt them in artificial neurons in order to exploit the respective benefits in machine learning
One of the key questions in neuroscience is how our brain self-organises to efficiently process info...
Are single neocortical neurons as powerful as multi-layered networks? A recent compartmental modelin...
Biological neural networks are systems of extraordinary computational capabilities shaped by evoluti...
This article highlights specific features of biological neurons and their dendritic trees, whose ado...
In this paper, we discuss the nonlinear computational power provided by dendrites in biological and ...
The significant role of dendritic processing within neuronal networks has become increasingly clear....
This paper addresses the problem of how dendritic topology and other properties of a neuron can dete...
Biologically inspired spiking neural networks are highly promising, but remain simplified omitting r...
2019-04-26In this thesis two biologically inspired projects are designed and implemented in the fiel...
A major challenge in neuroscience is to reverse engineer the brain and understand its information pr...
The paper discusses an analogue neural network concept in which the neuron is split up into parts (m...
Artificial neural networks, taking inspiration from biological neurons, have become an invaluable to...
The discovery of binary dendritic events such as local NMDA spikes in dendritic subbranches led to t...
Dendritic processing multiplies the computational power of a single neuron by enabling the processin...
Thesis: Ph. D. in Neuroscience, Massachusetts Institute of Technology, Department of Brain and Cogni...
One of the key questions in neuroscience is how our brain self-organises to efficiently process info...
Are single neocortical neurons as powerful as multi-layered networks? A recent compartmental modelin...
Biological neural networks are systems of extraordinary computational capabilities shaped by evoluti...
This article highlights specific features of biological neurons and their dendritic trees, whose ado...
In this paper, we discuss the nonlinear computational power provided by dendrites in biological and ...
The significant role of dendritic processing within neuronal networks has become increasingly clear....
This paper addresses the problem of how dendritic topology and other properties of a neuron can dete...
Biologically inspired spiking neural networks are highly promising, but remain simplified omitting r...
2019-04-26In this thesis two biologically inspired projects are designed and implemented in the fiel...
A major challenge in neuroscience is to reverse engineer the brain and understand its information pr...
The paper discusses an analogue neural network concept in which the neuron is split up into parts (m...
Artificial neural networks, taking inspiration from biological neurons, have become an invaluable to...
The discovery of binary dendritic events such as local NMDA spikes in dendritic subbranches led to t...
Dendritic processing multiplies the computational power of a single neuron by enabling the processin...
Thesis: Ph. D. in Neuroscience, Massachusetts Institute of Technology, Department of Brain and Cogni...
One of the key questions in neuroscience is how our brain self-organises to efficiently process info...
Are single neocortical neurons as powerful as multi-layered networks? A recent compartmental modelin...
Biological neural networks are systems of extraordinary computational capabilities shaped by evoluti...