Provided is a neuromorphic system using a neuron circuit. The neuromorphic system includes: one or two or more neuron circuits configured to output a firing signal according to signals input from a synapse array; a homeostatic circuit for each neuron circuit; and a global self-controller configured
Provided is a neuromorphic system using a neuron circuit. The neuromorphic system includes: one or two or more neuron circuits configured to output a firing signal according to signals input from a synapse array; a homeostatic circuit for each neuron circuit; and a global self-controller configured to generate and provide control signals for the neuron circuits by using the firing signal output from the neuron circuits. The neuron circuit includes a neuromorphic device and an output circuit that outputs the firing signal of the neuromorphic device. The global self-controller generates and supplies a reset signal to the neuromorphic device of the fired neuron circuit, and the global self-controller generates and supplies a lateral inhibition signal to the neuromorphic device of the non-fired neuron circuit. The homeostatic circuit alleviates inhibition of other neurons by the neurons with a predominant firing function.
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1. A neuromorphic system comprising: one or two or more neuron circuits configured to output a firing signal according to signals input from a synapse array; anda global self-controller configured to generate and provide control signals for the neuron circuits by using the firing signal output from
1. A neuromorphic system comprising: one or two or more neuron circuits configured to output a firing signal according to signals input from a synapse array; anda global self-controller configured to generate and provide control signals for the neuron circuits by using the firing signal output from the neuron circuits,wherein the neuron circuit includes:a neuromorphic device configured to accumulate charges according to the signal input from the synapse array and to allow a current to suddenly flow when a potential due to the accumulated charges reaches a threshold value;an output circuit connected to one end of the neuromorphic device and outputting the firing signal according to an output signal of the neuromorphic device; anda first switching device configured to be located between one end of the neuromorphic device and the output circuit and to control an electrical connection between the neuromorphic device and the output circuit. 2. The neuromorphic system according to claim 1, wherein the neuromorphic device includes:a first semiconductor region provided on a substrate, the first semiconductor region having a horizontally or vertically thin flat structure;first, second, third, and fourth doped regions provided in the first semiconductor region;a first insulating film configured so that at least the second and third doped regions among the doped regions are separated from the substrate by a predetermined distance;a first gate electrode located on one side of the second or third doped region, the first gate electrode being electrically insulated from the second and third doped regions; anda first gate insulating film stack provided at least between one side of the second or third doped region and the first gate electrode, andwherein the neuron circuit outputs the firing signal to the global self-controller according to the signal input from the synapse array to the first gate electrode of the neuromorphic device. 3. The neuromorphic system according to claim 2, wherein the first gate electrode of the neuromorphic device is connected to the synapse array through a current mirror circuit, andwherein the neuromorphic device implements an integrating function of the neuron by storing or removing charges in or from the first gate insulating film stack according to the signal applied from the synapse array. 4. The neuromorphic system according to claim 1, wherein, when the firing signal is input from one neuron circuit, the global self-controller generates and supplies a reset signal for the neuromorphic device of the fired neuron circuit, and the global self-controller generates and supplies a lateral inhibition signal for the neuromorphic device of the non-fired neuron circuit. 5. The neuromorphic system according to claim 1, wherein, when the firing signal is input from one neuron circuit, the global self-controller generates a turn-off signal for the first switching devices included in the neuron circuits and supplies the turn-off signal to the neuron circuits so that the first switching devices are turned off and no current flows in the neuromorphic device. 6. The neuromorphic system according to claim 1, wherein the neuron circuit further includes:a second switching device configured to be connected in parallel to the neuromorphic device and to be driven by an output signal of the output circuit; anda feedback circuit connected to the output circuit, andwherein the second switching device is configured to be turned on by the firing signal output from the output circuit and to improve the firing function of the neuron circuit. 7. The neuromorphic system according to claim 1, further comprising one or two or more homeostatic circuits provided corresponding to the respective neuron circuits, wherein an input terminal of the homeostatic circuit is connected to an output terminal of the output circuit of the neuron circuit, and an output terminal of the homeostatic circuit is connected to a second gate electrode of the neuromorphic device, andwherein the homeostatic circuit controls a voltage applied to the second gate electrode of the neuromorphic device according to a signal of the output terminal of the output circuit to adjust a firing threshold voltage of the neuromorphic device and adjust a firing rate of the neuron circuit so as to be capable of implementing a homeostasis function of neurons. 8. The neuromorphic system according to claim 7, wherein the homeostatic circuit includes: an individual current mirror circuit connected to the output terminal of the neuron circuit;a common current mirror circuit commonly connected to all the neuron circuits connected to the global self-controller; anda charge storage device as a device capable of storing charges configured to accumulate the charges by currents flowing in the individual current mirror circuit and the common current mirror circuit and to be connected to the second gate electrode of the neuromorphic device of the neuron circuit. 9. The neuromorphic system according to claim 8, wherein when the neuron circuit is fired, the homeostatic circuit allows the firing signal to be transmitted to the individual current mirror and accumulates the charges in the charge storage device connected to the fired neuron circuit so as to increase a threshold voltage of the fired neuron circuit, andthe homeostatic circuit allows the firing signal to be transmitted to the common current mirror and discharges the charges accumulated in the charge storage device connected to the non-fired neuron circuit so as to decrease the threshold voltage of the non-fired neuron circuit. 10. The neuromorphic system according to claim 1, wherein the global self-controller includes:a global self-control module that generates a reset pulse when the firing signal is input from one of the one or two or more neuron circuits and outputs the reset pulse; andone or two or more individual control modules that generate signals for controlling the respective neuron circuits according to the reset pulse and the firing signal input from the neuron circuits and output the signals to corresponding neuron circuits, andwherein the global self-controller generates control signals for the neuron circuits by using the firing signals input from the neuron circuits and supplies the control signals to the neuron circuits. 11. The neuromorphic system according to claim 10, wherein the global self-control module includes: an extended pulse generator that extends a pulse width of the input firing signal and outputs the firing signal;a voltage level shifter that generates the reset pulse by increasing a size of the firing signal having the extended pulse width and outputs the reset pulse to the individual control modules; andan SW1 driving module that generates a turn-off signal for the first switching device by using the firing signal having the extended pulse width and outputs the turn-off signal to each neuron circuit. 12. The neuromorphic system according to claim 10, wherein the global self-control module includes: a switch controller that generates a predetermined selection signal necessary for selecting the reset signal and outputs the selection signal when the firing signal is input from the neuron circuit; andan LI/Reset signal selection switch that selects one of the reset signal and a lateral inhibition signal according to signals input from the switch controller and the global self-control module and outputs the selected signal to the neuromorphic device of the neuron circuit. 13. The neuromorphic system according to claim 12, wherein the LI/Reset signal selection switch selects and outputs the reset signal when the selection signal is input from the switch controller and the reset pulse is input from the global self-control module, and the LI/Reset signal selection switch selects and outputs the lateral inhibition signal when no selection signal is input from the switch controller. 14. The neuromorphic system according to claim 1, wherein the output circuit is configured with one of: an inverter that inverts and outputs an input signal, anda current-voltage converter that converts an input current into a voltage and outputs the voltage.
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