Feedback control in active sensing: rat exploratory whisking is modulated by environmental contact

Mitchinson, Ben; Martin, Chris; Grant, Robyn A.; Prescott, Tony J.

doi:10.1098/rspb.2006.0347

Cited by 250 publications

(331 citation statements)

References 45 publications

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“…As previously reported [19], the interaction between this excitation and this suppression often leads to rapid periodic interaction with the surface (something like 'tapping') by contacting whiskers (this can be seen in some of the supplementary videos). This mix of excitatory and inhibitory influences may be a useful model of rat behaviour [34], and may act to maximize the number of contacts that occur whilst normalizing the depth of those contacts. The whisker movement that results during tracking has reduced amplitude and more protracted average angle, these being the main features described by Munz et al [23] and Berg et al [28].…”

Section: Controlmentioning

confidence: 99%

Biomimetic tactile target acquisition, tracking and capture

Mitchinson

Pearson

Pipe

et al. 2014

Robotics and Autonomous Systems

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Section: Controlmentioning

confidence: 99%

Biomimetic tactile target acquisition, tracking and capture

Mitchinson

Pearson

Pipe

et al. 2014

Robotics and Autonomous Systems

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“…Second, behavioral data obtained by Carvell and Simons [10], in animals that were trained to discriminate texture for reward using only their macrovibrissae, provides evidence of an "active touch" strategy [25] that rats may use to optimise their texture discrimination capabilities. Specifically, they observed that while some of the longer, more caudal, macrovibrissae were whisked back and forth across the target surface, presumably to obtain texture-related information, a number of the smaller rostralmost hairs remained in a "relatively motionless, protracted state [...] never losing contact with the surface" (p. 2641).…”

Section: Discussionmentioning

confidence: 98%

“…Inhibitory and excitatory projections from the strain sensors at the base of each whisker would modulate the behaviour of the pattern generators when contacts were made with the environment, thus affecting the drive signals to the BioMetal wires. This feedback control system was adopted as it best fits both anatomical (no proprioception in mystacial musculature [14]) and ethological observations (contact mediated adaptation [24]) of rats. For further details of the robot whisker morphology, actuation, and transductions mechanisms see [26], [29].…”

Section: Artificial Whisker Systemmentioning

confidence: 99%

Contact type dependency of texture classification in a whiskered mobile robot

et al. 2009

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Actuated artificial whiskers modeled on rat macrovibrissae can provide effective tactile sensor systems for autonomous robots. This article focuses on texture classification using artificial whiskers and addresses a limitation of previous studies, namely, their use of whisker deflection signals obtained under relatively constrained experimental conditions. Here we consider the classification of signals obtained from a whiskered robot required to explore different surface textures from a range of orientations and distances. This procedure resulted in a variety of deflection signals for any given texture. Using a standard Gaussian classifier we show, using both hand-picked features and ones derived from studies of rat vibrissal processing, that a robust rough-smooth discrimination is achievable without any knowledge of how the whisker interacts with the investigated object. On the other hand, finer discriminations appear to require knowledge of the target's relative position and/or of the manner in which the whisker contact its surface. (146 words)

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“…A common form of contact-related modulation, observed in multiple species [7,38], is that whisker protraction is controlled following a unilateral contact, such that whiskers on the side of the snout ipsilateral to the contact are reined in and those on the contralateral side brought forward, sometimes contacting another part of the encountered obstruction and resulting in bilateral contact. We refer to this observation as contact-induced asymmetry (CIA, [7]).…”

Section: Introductionmentioning

confidence: 99%

Biomimetic vibrissal sensing for robots

Pearson

Mitchinson

Sullivan

et al. 2011

Phil. Trans. R. Soc. B

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Active vibrissal touch can be used to replace or to supplement sensory systems such as computer vision and, therefore, improve the sensory capacity of mobile robots. This paper describes how arrays of whisker-like touch sensors have been incorporated onto mobile robot platforms taking inspiration from biology for their morphology and control. There were two motivations for this work: first, to build a physical platform on which to model, and therefore test, recent neuroethological hypotheses about vibrissal touch; second, to exploit the control strategies and morphology observed in the biological analogue to maximize the quality and quantity of tactile sensory information derived from the artificial whisker array. We describe the design of a new whiskered robot, Shrewbot, endowed with a biomimetic array of individually controlled whiskers and a neuroethologically inspired whisking pattern generation mechanism. We then present results showing how the morphology of the whisker array shapes the sensory surface surrounding the robot's head, and demonstrate the impact of active touch control on the sensory information that can be acquired by the robot. We show that adopting bio-inspired, low latency motor control of the rhythmic motion of the whiskers in response to contact-induced stimuli usefully constrains the sensory range, while also maximizing the number of whisker contacts. The robot experiments also demonstrate that the sensory consequences of active touch control can be usefully investigated in biomimetic robots.

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Feedback control in active sensing: rat exploratory whisking is modulated by environmental contact

Cited by 250 publications

References 45 publications

Biomimetic tactile target acquisition, tracking and capture

Biomimetic tactile target acquisition, tracking and capture

Contact type dependency of texture classification in a whiskered mobile robot

Biomimetic vibrissal sensing for robots

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