Modeling neuromorphic persistent firing networks
Neurons are believed to be the brain computational engines of the brain. A recent discovery in neurophysiology reveals that interneurons can slowly integrate spiking, share the output across a coupled network of axons and respond with persistent firing even in the absence of input to the soma or den...
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2015
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sg-smu-ink.sis_research-83922022-10-13T07:29:29Z Modeling neuromorphic persistent firing networks NING, Ning LI, Guoqi HE, Wei HUANG, Kejie PAN, Li RAMANATHAN, Kiruthika ZHAO, Rong SHI, Luping Neurons are believed to be the brain computational engines of the brain. A recent discovery in neurophysiology reveals that interneurons can slowly integrate spiking, share the output across a coupled network of axons and respond with persistent firing even in the absence of input to the soma or dendrites, which has not been understood and could be very important for exploring the mechanism of human cognition. The conventional models are incapable of simulating the important newly-discovered phenomenon of persistent firing induced by axonal slow integration. In this paper, we propose a computationally efficient model of neurons through modeling the axon as a slow leaky integrator, which captures almost all-known neural behaviors. The model controls the switching of axonal firing dynamics between passive conduction mode and persistent firing mode. The interplay between the axonal integrated potential and its multiple thresholds in axon precisely determines the persistent firing dynamics of neurons. We also present a persistent firing polychronous spiking network which exhibits asynchronous dynamics indicating that this computationally efficient model is not only bio-plausible, but also suitable for large scale spiking network simulations. The implications of this network and the analog circuit design for exploring the relationship between working memory and persistent firing enable developing a spiking networkbased memory and bio-inspired computer systems. 2015-01-01T08:00:00Z text application/pdf https://ink.library.smu.edu.sg/sis_research/7389 info:doi/10.4236/ijis.2015.52009 https://ink.library.smu.edu.sg/context/sis_research/article/8392/viewcontent/IJIS_2015013016221485.pdf http://creativecommons.org/licenses/by-nc-nd/4.0/ Research Collection School Of Computing and Information Systems eng Institutional Knowledge at Singapore Management University Neuron Model Neuromorphic Persistent Firing Slow Integration Spiking Network Working Memory Databases and Information Systems OS and Networks |
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Neuron Model Neuromorphic Persistent Firing Slow Integration Spiking Network Working Memory Databases and Information Systems OS and Networks |
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Neuron Model Neuromorphic Persistent Firing Slow Integration Spiking Network Working Memory Databases and Information Systems OS and Networks NING, Ning LI, Guoqi HE, Wei HUANG, Kejie PAN, Li RAMANATHAN, Kiruthika ZHAO, Rong SHI, Luping Modeling neuromorphic persistent firing networks |
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Neurons are believed to be the brain computational engines of the brain. A recent discovery in neurophysiology reveals that interneurons can slowly integrate spiking, share the output across a coupled network of axons and respond with persistent firing even in the absence of input to the soma or dendrites, which has not been understood and could be very important for exploring the mechanism of human cognition. The conventional models are incapable of simulating the important newly-discovered phenomenon of persistent firing induced by axonal slow integration. In this paper, we propose a computationally efficient model of neurons through modeling the axon as a slow leaky integrator, which captures almost all-known neural behaviors. The model controls the switching of axonal firing dynamics between passive conduction mode and persistent firing mode. The interplay between the axonal integrated potential and its multiple thresholds in axon precisely determines the persistent firing dynamics of neurons. We also present a persistent firing polychronous spiking network which exhibits asynchronous dynamics indicating that this computationally efficient model is not only bio-plausible, but also suitable for large scale spiking network simulations. The implications of this network and the analog circuit design for exploring the relationship between working memory and persistent firing enable developing a spiking networkbased memory and bio-inspired computer systems. |
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NING, Ning LI, Guoqi HE, Wei HUANG, Kejie PAN, Li RAMANATHAN, Kiruthika ZHAO, Rong SHI, Luping |
| author_facet |
NING, Ning LI, Guoqi HE, Wei HUANG, Kejie PAN, Li RAMANATHAN, Kiruthika ZHAO, Rong SHI, Luping |
| author_sort |
NING, Ning |
| title |
Modeling neuromorphic persistent firing networks |
| title_short |
Modeling neuromorphic persistent firing networks |
| title_full |
Modeling neuromorphic persistent firing networks |
| title_fullStr |
Modeling neuromorphic persistent firing networks |
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Modeling neuromorphic persistent firing networks |
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modeling neuromorphic persistent firing networks |
| publisher |
Institutional Knowledge at Singapore Management University |
| publishDate |
2015 |
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https://ink.library.smu.edu.sg/sis_research/7389 https://ink.library.smu.edu.sg/context/sis_research/article/8392/viewcontent/IJIS_2015013016221485.pdf |
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