Towards deep learning with segregated dendrites
Deep learning has led to significant advances in artificial intelligence, in part, by adopting strategies motivated by neurophysiology. However, it is unclear whether deep learning could occur in the real brain. Here, we show that a deep learning algorithm that utilizes multi-compartment neurons mig...
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2017-12-01
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| Online Access: | https://elifesciences.org/articles/22901 |
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doaj-caaf8da698514d049eceb8431ecab1dd2021-05-05T13:58:57ZengeLife Sciences Publications LtdeLife2050-084X2017-12-01610.7554/eLife.22901Towards deep learning with segregated dendritesJordan Guerguiev0https://orcid.org/0000-0002-6751-8782Timothy P Lillicrap1Blake A Richards2https://orcid.org/0000-0001-9662-2151Department of Biological Sciences, University of Toronto Scarborough, Toronto, Canada; Department of Cell and Systems Biology, University of Toronto, Toronto, CanadaDeepMind, London, United KingdomDepartment of Biological Sciences, University of Toronto Scarborough, Toronto, Canada; Department of Cell and Systems Biology, University of Toronto, Toronto, Canada; Learning in Machines and Brains Program, Canadian Institute for Advanced Research, Toronto, CanadaDeep learning has led to significant advances in artificial intelligence, in part, by adopting strategies motivated by neurophysiology. However, it is unclear whether deep learning could occur in the real brain. Here, we show that a deep learning algorithm that utilizes multi-compartment neurons might help us to understand how the neocortex optimizes cost functions. Like neocortical pyramidal neurons, neurons in our model receive sensory information and higher-order feedback in electrotonically segregated compartments. Thanks to this segregation, neurons in different layers of the network can coordinate synaptic weight updates. As a result, the network learns to categorize images better than a single layer network. Furthermore, we show that our algorithm takes advantage of multilayer architectures to identify useful higher-order representations—the hallmark of deep learning. This work demonstrates that deep learning can be achieved using segregated dendritic compartments, which may help to explain the morphology of neocortical pyramidal neurons.https://elifesciences.org/articles/22901deep learningdendritic morphologyneocortexcredit assignmentfeedback alignmenttarget propagation |
| collection |
DOAJ |
| language |
English |
| format |
Article |
| sources |
DOAJ |
| author |
Jordan Guerguiev Timothy P Lillicrap Blake A Richards |
| spellingShingle |
Jordan Guerguiev Timothy P Lillicrap Blake A Richards Towards deep learning with segregated dendrites eLife deep learning dendritic morphology neocortex credit assignment feedback alignment target propagation |
| author_facet |
Jordan Guerguiev Timothy P Lillicrap Blake A Richards |
| author_sort |
Jordan Guerguiev |
| title |
Towards deep learning with segregated dendrites |
| title_short |
Towards deep learning with segregated dendrites |
| title_full |
Towards deep learning with segregated dendrites |
| title_fullStr |
Towards deep learning with segregated dendrites |
| title_full_unstemmed |
Towards deep learning with segregated dendrites |
| title_sort |
towards deep learning with segregated dendrites |
| publisher |
eLife Sciences Publications Ltd |
| series |
eLife |
| issn |
2050-084X |
| publishDate |
2017-12-01 |
| description |
Deep learning has led to significant advances in artificial intelligence, in part, by adopting strategies motivated by neurophysiology. However, it is unclear whether deep learning could occur in the real brain. Here, we show that a deep learning algorithm that utilizes multi-compartment neurons might help us to understand how the neocortex optimizes cost functions. Like neocortical pyramidal neurons, neurons in our model receive sensory information and higher-order feedback in electrotonically segregated compartments. Thanks to this segregation, neurons in different layers of the network can coordinate synaptic weight updates. As a result, the network learns to categorize images better than a single layer network. Furthermore, we show that our algorithm takes advantage of multilayer architectures to identify useful higher-order representations—the hallmark of deep learning. This work demonstrates that deep learning can be achieved using segregated dendritic compartments, which may help to explain the morphology of neocortical pyramidal neurons. |
| topic |
deep learning dendritic morphology neocortex credit assignment feedback alignment target propagation |
| url |
https://elifesciences.org/articles/22901 |
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