The Etruscan shrew, one of the world’s tiniest mammals, measuring around 4 centimetres long, is the inspiration for a ground-breaking new robot developed to use sophisticated whiskers to find its way around.
(PressZoom) - The Etruscan shrew, one of the world’s tiniest mammals, measuring around 4 centimetres long, is the inspiration for a ground-breaking new robot developed to use sophisticated whiskers to find its way around.
The Shrewbot is the latest in a series of robots which use ‘active touch’ rather than vision to navigate their environment.Â The Shrewbot has been developed at Bristol Robotics Laboratory (BRL) in collaboration with the University of Sheffield Active Touch Laboratory as part of the BIOTACT project, Professor Tony Pipe (UWE Bristol) and Professor Tony Prescott (University of Sheffield) are working on the Shrewbot project with a number of partners.Â BRL is a collaboration between UWE Bristol and the University of Bristol.
The Sheffield Centre for Robotics (SCentRo) combines the expertise from both the University of Sheffield and Sheffield Hallam University.
The Etruscan shrew is nocturnal, relying on its whiskers to find, track and capture its prey – often the same size as itself.Â The efficiency of this tiny creature has inspired scientists to look at ways of replicating the shrew’s whiskers to enable robots to find their way around without the use of vision.
Vision is the sense that has so far been most extensively studied and understood in terms of how it could be used for autonomous robots.Â However there are numerous examples in nature, particularly in nocturnal creatures, where ‘active touch’ plays a primary role in how the animal finds its way around and how it behaves.
The shrew sweeps its whiskers back and forth at high speeds and through picking up vibrations it gathers information from the environment such as the location, shape and texture of objects.Â It then stores this information in its memory.Â
Professor Tony Prescott (University of Sheffield) says, “When the whiskers touch an object this causes them to vibrate and the vibration pattern is picked up by sensitive cells in the hair follicle at the base of the whisker.Â These patterns are turned into an electrical signal which is sent to the brain, enabling the mammal to make instant decisions about its environment to help it move around or catch prey.Â The whiskers have another advantage over some other forms of tactile touch.Â Whiskers themselves are easily replaceable since the sensory cells are at the base of the whisker, not the top, unlike our fingers for example, which are more easily damaged and hard to replace.”
The research has developed man-made whiskers that can move separately and are mounted on a mobile robot.Â They mimic the capability of the shrew by capturing information in the robot’s environment and allow it to make decisions about how to move in a particular environment.
Professor Tony Pipe (UWE, Bristol) explains, “There are real advantages to this form of tactile sensing for robots that we are just beginning to understand.Â For example this whisker technology could have applications in dark, dangerous or smoke filled environments which are unsafe for humans, where in future we might want robots to go.Â Overall this project has taken us to a new level in our understanding of active touch sensing and in the use of whisker-like sensors in intelligent machines.”
BRL is a partner in the BIOTACT consortium and, together with the University of Sheffield, is responsible for the majority of the robotics aspects of the project. BIOTACT is a four-year research project funded by the Seventh Research Programme (FP7) of the European Union and involves nine research groups in 7 countries.
Further information: BIOTACT is a four-year research project funded by the Seventh Research Programme (FP7) of the European Union and involves nine research groups in 7 countries. The aim of BIOTACT is to develop novel tactile sensory technologies inspired by the vibrissal (whisker) sensory systems of mammals such as rats and shrews. BIOTACT is one of several projects funded under the FP7 initiative on Bio-ICT Convergence.
Bristol Robotics Laboratory (BRL) is the largest multi-disciplinary robotics facility in the UK with an international reputation in advanced robotics research. The BRL mission is to understand the science, engineering and social role of robotics and embedded intelligence and to create autonomous devices capable of working independently, with each other, or with people.
The Sheffield Centre for Robotics (SCentRo) combines the expertise from both University of Sheffield and Sheffield Hallam University in a bid to boost research into the creation of animal-like robots, self-driving cars, robots for the farms of the future and robots that can intelligently communicate with humans. SCentRo unites the fields of engineering, psychology, computer science and robotics to make advances that will include robots with flexible, safe bodies and human-like sensory and learning capabilities that will allow them to learn from experience as humans do and work more closely with people than current factory robots.
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