TY - JOUR
T1 - Silicon modeling of the Mihalas–Niebur neuron
AU - Folowosele, Fopefolu
AU - Hamilton, Tara Julia
AU - Etienne-Cummings, Ralph
PY - 2011
Y1 - 2011
N2 - There are a number of spiking and bursting neuron models with varying levels of complexity, ranging from the simple integrate-and-fire model to the more complex Hodgkin-Huxley model. The simpler models tend to be easily implemented in silicon but yet not biologically plausible. Conversely, the more complex models tend to occupy a large area although they are more biologically plausible. In this paper, we present the 0.5 μm complementary metal-oxide-semiconductor (CMOS) implementation of the Mihalaş-Niebur neuron model-a generalized model of the leaky integrate-and-fire neuron with adaptive threshold-that is able to produce most of the known spiking and bursting patterns that have been observed in biology. Our implementation modifies the original proposed model, making it more amenable to CMOS implementation and more biologically plausible. All but one of the spiking properties-tonic spiking, class 1 spiking, phasic spiking, hyperpolarized spiking, rebound spiking, spike frequency adaptation, accommodation, threshold variability, integrator and input bistability-are demonstrated in this model.
AB - There are a number of spiking and bursting neuron models with varying levels of complexity, ranging from the simple integrate-and-fire model to the more complex Hodgkin-Huxley model. The simpler models tend to be easily implemented in silicon but yet not biologically plausible. Conversely, the more complex models tend to occupy a large area although they are more biologically plausible. In this paper, we present the 0.5 μm complementary metal-oxide-semiconductor (CMOS) implementation of the Mihalaş-Niebur neuron model-a generalized model of the leaky integrate-and-fire neuron with adaptive threshold-that is able to produce most of the known spiking and bursting patterns that have been observed in biology. Our implementation modifies the original proposed model, making it more amenable to CMOS implementation and more biologically plausible. All but one of the spiking properties-tonic spiking, class 1 spiking, phasic spiking, hyperpolarized spiking, rebound spiking, spike frequency adaptation, accommodation, threshold variability, integrator and input bistability-are demonstrated in this model.
UR - http://handle.westernsydney.edu.au:8081/1959.7/uws:41907
U2 - 10.1109/TNN.2011.2167020
DO - 10.1109/TNN.2011.2167020
M3 - Article
SN - 1045-9227
VL - 22
SP - 1915
EP - 1927
JO - IEEE transactions on neural networks
JF - IEEE transactions on neural networks
IS - 12
ER -