Abstract
Giving robots the ability to classify surface textures requires appropriate sensors and algorithms. Inspired by the biology of human tactile perception, we implement a neurorobotic texture classifier with a recurrent spiking neural network, using a novel semisupervised approach for classifying dynamic stimuli. Input to the network is supplied by accelerometers mounted on a robotic arm. The sensor data are encoded by a heterogeneous population of neurons, modeled to match the spiking activity of mechanoreceptor cells. This activity is convolved by a hidden layer using bandpass filters to extract nonlinear frequency information from the spike trains. The resulting high-dimensional feature representation is then continuously classified using a neurally implemented support vector machine. We demonstrate that our system classifies 18 metal surface textures scanned in two opposite directions at a constant velocity. We also demonstrate that our approach significantly improves upon a baseline model that does not use the described feature extraction. This method can be performed in real-time using neuromorphic hardware, and can be extended to other applications that process dynamic stimuli online.
Highlights
H UMANS are remarkably adept at perceiving the environment using their sense of touch
We report performance on a set of 18 metal surface textures
1) Neural Engineering Framework: Our approach uses the NEF, which consists of three principles that enable the translation of a high-level mathematical description of a system into a biologically plausible model of spiking neurons and connection weight matrices [17]
Summary
H UMANS are remarkably adept at perceiving the environment using their sense of touch. By moving the fingertip across a surface, vibrations give rise to perceptual qualities such as roughness [1], stickiness, and slipperiness [2], [3]. Our goal is to draw inspiration from nature to give robots the ability to classify surface textures in realtime. This ability can be deployed within systems that need to classify tactile stimuli, such as those employed to automate quality control of textured surfaces. Dynamic robotic systems for tactile surface sensing have been developed using various technologies [5]. In this context, Manuscript received: August, 31, 2015; Revised November, 18, 2015; Accepted December, 22, 2015
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