Abstract
Neural coupled oscillators are a useful building block in numerous models and applications. They were analyzed extensively in theoretical studies and more recently in biologically realistic simulations of spiking neural networks. The advent of mixed-signal analog/digital neuromorphic electronic circuits provides new means for implementing neural coupled oscillators on compact, low-power, spiking neural network hardware platforms. However, their implementation on this noisy, low-precision and inhomogeneous computing substrate raises new challenges with regards to stability and controllability. In this work, we present a robust, spiking neural network model of neural coupled oscillators and validate it with an implementation on a mixed-signal neuromorphic processor. We demonstrate its robustness showing how to reliably control and modulate the oscillator’s frequency and phase shift, despite the variability of the silicon synapse and neuron properties. We show how this ultra-low power neural processing system can be used to build an adaptive cardiac pacemaker modulating the heart rate with respect to the respiration phases and compare it with surface ECG and respiratory signal recordings from dogs at rest. The implementation of our model in neuromorphic electronic hardware shows its robustness on a highly variable substrate and extends the toolbox for applications requiring rhythmic outputs such as pacemakers.
Highlights
Neural coupled oscillators are a useful building block in numerous models and applications
We propose to go one step further in adding biological realism to these models by implementing coupled oscillators using mixed-signal analog/digital neuromorphic electronic circuits that use the physics of transistors to emulate the biophysics of real neurons and synapses[25,26], and demonstrate a hardware Central Pattern Generators (CPGs) network that operates in real-time and that could be used in closed-loop applications to drive motors and actuators coupled to a wide variety of artificial and biological dynamical systems
We studied the relation between the parameters of the spiking neural network (SNN) model and the network’s oscillation properties to develop a structured tuning process to semi-automatically tune our network
Summary
Neural coupled oscillators are a useful building block in numerous models and applications. We propose to go one step further in adding biological realism to these models by implementing coupled oscillators using mixed-signal analog/digital neuromorphic electronic circuits that use the physics of transistors to emulate the biophysics of real neurons and synapses[25,26], and demonstrate a hardware CPG network that operates in real-time and that could be used in closed-loop applications to drive motors and actuators coupled to a wide variety of artificial and biological dynamical systems. In addition to being a useful research tool for studying neural circuits, they are ideal for implementing closed-loop interactive experiments, with direct and online access to the system parameters that govern their dynamics This technology is attractive for applications that require compact form-factors, high scalability, low weight, low power and that cannot resort to connecting to remote “cloud” computing services for signal processing[30,31,32,33]
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