TY - GEN
T1 - Single dendritic neuron with nonlinear computation capacity
T2 - 3rd IEEE International Conference on Progress in Informatics and Computing, PIC 2015
AU - Jiang, Tao
AU - Wang, Dizhou
AU - Ji, Junkai
AU - Todo, Yuki
AU - Gao, Shangce
N1 - Publisher Copyright:
© 2015 IEEE.
PY - 2016/6/10
Y1 - 2016/6/10
N2 - Recently, a series of theoretical studies have conjectured that synaptic nonlinearities in a dendritic tree could make individual neurons act more powerfully in complex computational operations. Each of the neurons has quite distinct morphologies of synapses and dendrites to determine what signals a neuron receives and how these signals are integrated. However, there is no effective model that can captures the nonlinearities among excitatory and inhibitory inputs while predicting the morphology and its evolution of synapses and dendrites. In this paper, we propose a new single neuron model with synaptic nonlinearities in a dendritic tree. The computation on neuron has a neuron-pruning function that can reduce dimension by removing useless synapses and dendrites during learning, forming a precise synaptic and dendritic morphology. The nonlinear interactions in a dendrite tree are expressed using the Boolean logic AND (conjunction), OR (disjunction) and NOT (negation). An error back propagation algorithm is used to train the neuron model. Furthermore, we apply the new model to the Exclusive OR (XOR) problem and it can solve the problem perfectly with the help of inhibitory synapses which demonstrate synaptic nonlinear computation and the neuron's ability to learn.
AB - Recently, a series of theoretical studies have conjectured that synaptic nonlinearities in a dendritic tree could make individual neurons act more powerfully in complex computational operations. Each of the neurons has quite distinct morphologies of synapses and dendrites to determine what signals a neuron receives and how these signals are integrated. However, there is no effective model that can captures the nonlinearities among excitatory and inhibitory inputs while predicting the morphology and its evolution of synapses and dendrites. In this paper, we propose a new single neuron model with synaptic nonlinearities in a dendritic tree. The computation on neuron has a neuron-pruning function that can reduce dimension by removing useless synapses and dendrites during learning, forming a precise synaptic and dendritic morphology. The nonlinear interactions in a dendrite tree are expressed using the Boolean logic AND (conjunction), OR (disjunction) and NOT (negation). An error back propagation algorithm is used to train the neuron model. Furthermore, we apply the new model to the Exclusive OR (XOR) problem and it can solve the problem perfectly with the help of inhibitory synapses which demonstrate synaptic nonlinear computation and the neuron's ability to learn.
UR - http://www.scopus.com/inward/record.url?scp=84979700545&partnerID=8YFLogxK
U2 - 10.1109/PIC.2015.7489802
DO - 10.1109/PIC.2015.7489802
M3 - 会議への寄与
AN - SCOPUS:84979700545
T3 - Proceedings of 2015 IEEE International Conference on Progress in Informatics and Computing, PIC 2015
SP - 20
EP - 24
BT - Proceedings of 2015 IEEE International Conference on Progress in Informatics and Computing, PIC 2015
A2 - Xiao, Liang
A2 - Wang, Yinglin
PB - Institute of Electrical and Electronics Engineers Inc.
Y2 - 18 December 2015 through 20 December 2015
ER -