From biokinematics to a robotic active vision system

Ouriel Barzilay; Lihi Zelnik-Manor; Yoram Gutfreund; Hermann Wagner; Alon Wolf

doi:10.1088/1748-3190/aa7728

From biokinematics to a robotic active vision system

Ouriel Barzilay
, Lihi Zelnik-Manor
, Yoram Gutfreund
, Hermann Wagner
, Alon Wolf

Research output: Contribution to journal › Article › peer-review

Abstract

Barn owls move their heads in very particular motions, compensating for the quasi-immovability of their eyes. These efficient predators often perform peering side-to-side head motions when scanning their surroundings and seeking prey. In this work, we use the head movements of barn owls as a model to bridge between biological active vision and machine vision. The biomotions are measured and used to actuate a specially built robot equipped with a depth camera for scanning. We hypothesize that the biomotions improve scan accuracy of static objects. Our experiments show that barn owl biomotion-based trajectories consistently improve scan accuracy when compared to intuitive scanning motions. This constitutes proof-of-concept evidence that the vision of robotic systems can be enhanced by bio-inspired viewpoint manipulation. Such biomimetic scanning systems can have many applications, e.g. manufacturing inspection or in autonomous robots.

Original language	English
Article number	056004
Journal	Bioinspiration and Biomimetics
Volume	12
Issue number	5
DOIs	https://doi.org/10.1088/1748-3190/aa7728
State	Published - 20 Sep 2017

Keywords

Active vision
Barn owls
Biokinematics
Biorobotics

ASJC Scopus subject areas

Biotechnology
Biophysics
Biochemistry
Molecular Medicine
Engineering (miscellaneous)

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

Access to Document

10.1088/1748-3190/aa7728

Cite this

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title = "From biokinematics to a robotic active vision system",

abstract = "Barn owls move their heads in very particular motions, compensating for the quasi-immovability of their eyes. These efficient predators often perform peering side-to-side head motions when scanning their surroundings and seeking prey. In this work, we use the head movements of barn owls as a model to bridge between biological active vision and machine vision. The biomotions are measured and used to actuate a specially built robot equipped with a depth camera for scanning. We hypothesize that the biomotions improve scan accuracy of static objects. Our experiments show that barn owl biomotion-based trajectories consistently improve scan accuracy when compared to intuitive scanning motions. This constitutes proof-of-concept evidence that the vision of robotic systems can be enhanced by bio-inspired viewpoint manipulation. Such biomimetic scanning systems can have many applications, e.g. manufacturing inspection or in autonomous robots.",

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AU - Barzilay, Ouriel

AU - Zelnik-Manor, Lihi

AU - Gutfreund, Yoram

AU - Wagner, Hermann

AU - Wolf, Alon

PY - 2017/9/20

Y1 - 2017/9/20

N2 - Barn owls move their heads in very particular motions, compensating for the quasi-immovability of their eyes. These efficient predators often perform peering side-to-side head motions when scanning their surroundings and seeking prey. In this work, we use the head movements of barn owls as a model to bridge between biological active vision and machine vision. The biomotions are measured and used to actuate a specially built robot equipped with a depth camera for scanning. We hypothesize that the biomotions improve scan accuracy of static objects. Our experiments show that barn owl biomotion-based trajectories consistently improve scan accuracy when compared to intuitive scanning motions. This constitutes proof-of-concept evidence that the vision of robotic systems can be enhanced by bio-inspired viewpoint manipulation. Such biomimetic scanning systems can have many applications, e.g. manufacturing inspection or in autonomous robots.

AB - Barn owls move their heads in very particular motions, compensating for the quasi-immovability of their eyes. These efficient predators often perform peering side-to-side head motions when scanning their surroundings and seeking prey. In this work, we use the head movements of barn owls as a model to bridge between biological active vision and machine vision. The biomotions are measured and used to actuate a specially built robot equipped with a depth camera for scanning. We hypothesize that the biomotions improve scan accuracy of static objects. Our experiments show that barn owl biomotion-based trajectories consistently improve scan accuracy when compared to intuitive scanning motions. This constitutes proof-of-concept evidence that the vision of robotic systems can be enhanced by bio-inspired viewpoint manipulation. Such biomimetic scanning systems can have many applications, e.g. manufacturing inspection or in autonomous robots.

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KW - Barn owls

KW - Biokinematics

KW - Biorobotics

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From biokinematics to a robotic active vision system

Abstract

Keywords

ASJC Scopus subject areas

UN SDGs

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