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1 Delay-Resistor Implementation of Integrators for Biomimic Artificial Neurons Richard B. Wells Bruce Barnes.

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Presentation on theme: "1 Delay-Resistor Implementation of Integrators for Biomimic Artificial Neurons Richard B. Wells Bruce Barnes."— Presentation transcript:

1 1 Delay-Resistor Implementation of Integrators for Biomimic Artificial Neurons Richard B. Wells Bruce Barnes

2 2 Background: Design Application: –Pulse-Mode Artificial Neurons and, in particular, –“Biomimic” Artificial Neurons Artificial Neurons Specifically Designed to Mimic the Signal Characteristics of Real Neurons

3 3 Design Objectives Mimic Asymmetrical Integration Properties of Biological Neurons Low Power Dissipation Small Chip Area This Circuit is Intended to Operate Within a Feedback Loop in a Biomimic Artificial Neuron

4 4 Hodgkin-Huxley Model The H-H Model Describes the Dynamics of Membrane Potential

5 5 Linear Prototype Model Low-Gain Non-Inverting Amplifier Open-Loop Gain Approximately 2.8 V/V “Delay Resistors” are P-MOSFETs

6 6 Linear Model Transfer Function Circuit Has 2 Real Poles, 1 Zero One Pole is a Dominant Pole This Results in Leaky-Integrator Transfer Function

7 7 The Non-Linear Circuit Circuit w/ Buffered Current Source Input

8 8 Transfer Characteristic Current In to Voltage Out

9 9 Integrator Response Fall Time vs. Vbias of Delay Resistors

10 10 Response to Pulse Input Vbias = 1.77 Volts

11 11 Thank You. Questions?

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