P
O:GE
TTY
OCTOBER 2016
Here’s one bot we definitely have a soft
spot for. Researchers at Harvard
Universityhavecreatedtheworld’sfirst
entirely soft robot capable of moving
around under its own steam.
Dubbed ‘octobot’ for obvious reasons,
therobotisaroundthesizeofanSD
memorycardandisabletomoveits
limbs pneumatically by transforming
liquid hydrogen peroxide fuel into a
much larger volume of gas. This gas
flowsfromacentralreservoirintothe
bot’sarms,inflatingthemlikeaballoon
and allowing it to move its limbs
without the need for rigid electronic
components such as batteries and
circuit boards.
“One long-standing vision for the
field of soft robotics has been to create
robots that are entirely soft, but the
struggle has always been in replacing
rigid components like batteries and
electronic controls with analogous soft
systems and then putting it all
together,” explained researcher
Robert Wood. “This research
demonstrates that we can easily
manufacturethekeycomponents
of a simple, entirely soft robot,
which lays the foundation for more
complex designs.”
Eachpartoftherobotwascustom
designed and put together using a
combination of various moulding
and3Dprintingtechniquesandis
simple to assemble.
“Thisresearchisaproofofconcept,”
said researcher Ryan Truby. “We hope
that our approach for creating
autonomous soft robots inspires
roboticists, material scientists and
researchers focused on advanced
manufacturing.”
The team is now working on creating
an octobot that can crawl, swim and
interact with its environment.
ROBOTS
MEET THE FIRST SOFT ROBOT
THAT CAN MOVE BY ITSELF
The squishy robot
is made entirely with
soft components
What did they do?
Researchers at the University of
California played a constant click track
to a sea lion named Ronan, rewarding
her with fish every time she nodded
along in time. They then upped the
ante by playing her Earth, Wind and
Fire’s funk-soul floor-filler Boogie
Wonderland and varying the tempo at
random intervals.
What did they find?
Not only was Ronan able to keep the
beat better than any other non-human
animal ever tested, she could also
quickly adapt to the new tempos. The
manner in which she did this suggests
that neurons in her auditory brain
centres first synchronised with
the rhythm and then passed on the
timing to the motor centres that
control movement.
Why did they do that?
Over the last decade chimps, bonobos,
parrots and budgerigars have all been
seen to move in time to music. By
further study, the researchers hope to
deepen their understanding of the
biological root s of musicalit y in humans.
SEA LION TAUGHT
TO KEEP A BEAT
THEY DID WHAT?!