Robust trajectory generation for robotic control on the neuromorphic research chip Loihi

TL;DR

This paper demonstrates a novel neuromorphic control algorithm using the Loihi chip, enabling reliable, complex robotic trajectory generation by leveraging a biologically-inspired anisotropic network model.

Contribution

It introduces a new network architecture on Loihi that encodes sequential patterns for robotic control, bridging the gap between hardware spiking activity and control timescales.

Findings

Reliable encoding of sequential neural activity patterns

Generation of multidimensional robotic trajectories

Robust control performance on neuromorphic hardware

Abstract

Neuromorphic hardware has several promising advantages compared to von Neumann architectures and is highly interesting for robot control. However, despite the high speed and energy efficiency of neuromorphic computing, algorithms utilizing this hardware in control scenarios are still rare. One problem is the transition from fast spiking activity on the hardware, which acts on a timescale of a few milliseconds, to a control-relevant timescale on the order of hundreds of milliseconds. Another problem is the execution of complex trajectories, which requires spiking activity to contain sufficient variability, while at the same time, for reliable performance, network dynamics must be adequately robust against noise. In this study we exploit a recently developed biologically-inspired spiking neural network model, the so-called anisotropic network. We identified and transferred the core principles of the anisotropic network to neuromorphic hardware using Intel's neuromorphic research chip Loihi and validated the system on trajectories from a motor-control task performed by a robot arm. We developed a network architecture including the anisotropic network and a pooling layer which allows fast spike read-out from the chip and performs an inherent regularization. With this, we show that the anisotropic network on Loihi reliably encodes sequential patterns of neural activity, each representing a robotic action, and that the patterns allow the generation of multidimensional trajectories on control-relevant timescales. Taken together, our study presents a new algorithm that allows the generation of complex robotic movements as a building block for robotic control using state of the art neuromorphic hardware.