Approaching Retinal Ganglion Cell Modeling and FPGA Implementation for Robotics.

Alejandro Linares-Barranco,Tobi Delbruck,Francisco Gomez-Rodriguez,Diederik Moeys,Hongjie Liu,Antonio Rios-Navarro

doi:10.3390/e20060475

Alejandro Linares-Barranco, Tobi Delbruck + Show 4 more

Open Access

https://doi.org/10.3390/e20060475

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Abstract

Taking inspiration from biology to solve engineering problems using the organizing principles of biological neural computation is the aim of the field of neuromorphic engineering. This field has demonstrated success in sensor based applications (vision and audition) as well as in cognition and actuators. This paper is focused on mimicking the approaching detection functionality of the retina that is computed by one type of Retinal Ganglion Cell (RGC) and its application to robotics. These RGCs transmit action potentials when an expanding object is detected. In this work we compare the software and hardware logic FPGA implementations of this approaching function and the hardware latency when applied to robots, as an attention/reaction mechanism. The visual input for these cells comes from an asynchronous event-driven Dynamic Vision Sensor, which leads to an end-to-end event based processing system. The software model has been developed in Java, and computed with an average processing time per event of 370 ns on a NUC embedded computer. The output firing rate for an approaching object depends on the cell parameters that represent the needed number of input events to reach the firing threshold. For the hardware implementation, on a Spartan 6 FPGA, the processing time is reduced to 160 ns/event with the clock running at 50 MHz. The entropy has been calculated to demonstrate that the system is not totally deterministic in response to approaching objects because of several bioinspired characteristics. It has been measured that a Summit XL mobile robot can react to an approaching object in 90 ms, which can be used as an attentional mechanism. This is faster than similar event-based approaches in robotics and equivalent to human reaction latencies to visual stimulus.

Highlights

The biological retina is the extension of the brain that perceives visual information
We present the results of the biological model implemented in software and hardware, which is presented in details in further sections, and a comparison between its application in a robotic scenario and biological responses
This paper offers software and field programmable gate array (FPGA) implementation of the approach sensitivity cell (AC) model for real time detection of expanding dark objects and its application in robotic for obstacle avoidance

Summary

Introduction

The biological retina is the extension of the brain that perceives visual information. Visual processing begins when photons stimulate the light-sensitive photo-receptor rod and cone cells in the retina. Bipolar cells are in charge of detecting luminosity changes. These cells convert the information into electrical signals and send them through intermediate networked layers of cells to 15–20 types of retinal ganglion cells. They perform visual processing before visual information arrives to the visual cortex in the brain. In the central nervous system, high priority information arrives first to the brain so it is processed in a higher priority, or even in an involuntary and reflexive way

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