© Teng Han and Abhijit Karnik Bristol Interaction and Graphics

'cubed' webzine

Anti-allergy parasite
Pancreas protector
Pop hit detector
Body Sensitive Cancer Treatment
Cheaper Smarter phones
Sports Training Tool
Light energy harvesting
Kitchen sink French
Clever cameras
Catalytic clothing
Smart surveillance
Super Broccoli
Kick and click
Pico secure access
Smartphone in Orbit
3D printed plane
Transmitting Data With Light
Brain cell bank
Energy for all seasons
Life-Saving Frogs
Dolphin Therapy
Rainbow money
In a Heartbeat
Restoring Speech
Safer Mosquitoes
Visualising Landscape Changes
Drumming Denim
Genetic clues for Alzheimer’s
Shower-Powered Radio
Assisted-Living Home
Fast-Scan Security
Keeping The Beat
Starfish non-stick drugs
Common Drug Could Reduce Cancer Risk
The Carbon Planet
3D Movie Tool
New Skin for Buildings
Pole Vaulting Pterosaurs
Bees Solve Problem
Rubber Tree Breakthrough
The Camouflage of Cats
Spotting PTSD
Spray on Clothes
The Biology of Thinking
Sphere TV
Driverless bus
Virtual London

University of Bristol

Bristol Interaction Group

Gestural Interaction Group

Further Information about group members and their research

cubed logo © British Council

Kick and Click

Leg action
Exploring alternative ways we can interact with our mobile devices is the work of the Gesture-based Interaction research team, part of the Interaction and Graphics Group at Bristol University. They are finding ‘footie’ to be an effective navigation tool, with kicking gestures being used for ‘hands-free’ communication.

Finding a way to detect gestures, led the team to the Kinect for Microsoft Xbox camera system. A big component of their work was producing the algorithms to register that a leg had moved in a particular way. The team believes that motion-sensing cameras will become standard in mobile phones.

How gestures work
Dr Jason Alexander, now teaching at the University of Lancaster, and part of the team, describes their approach: ‘once we established that you could interact using your leg, we produced a lot of algorithms to detect how far forward, how fast, and what angle from a straightforward position you had moved your leg. Then we translated these into gestures we could use for interactions.’

Their first significant insight, Alexander continues, ‘was that people can regularly and accurately kick in five different directions and at 180o in front of them. So if you are creating a menu, you shouldn’t put more than five items in that menu, otherwise people will struggle to select the correct item.’ Their second finding was whether people could vary the velocity of their kick to scroll around a screen. Their results showed two options. People weren’t very good at kicking at different speeds, but could kick accurately either slowly or fast.

© Teng Han and Abhijit Karnik Bristol Interaction and Graphics

Refining kick commands
The next step is integrating the programming for interpreting the gestures into a mobile device, testing it and putting it out in the real world. For now, they are busy refining the gestural commands. Alexander asks, ‘if you were kicking forward would people expect their screen to move forward or backward?’ Questions like this need to be explored.  

The team believe that most of the functions on a mobile phone could be mapped to a kick gesture if we wish them to be. So when our hands are full, kicking our favourite tunes to play on our mobiles could be our default selection.

LearnEnglish Science activities
Why not do a language activity based on this cubed story on Kick and Click? You can double-click on any word on this page for a dictionary definition.

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