She challenged a packed audience in the Interdisciplinary Science and Engineering
Complex on Tuesday to imagine a world where robots free us to be more creative
by taking care of all our physical tasks—from playing with our pets to
performing surgery without an incision.
As
director of the Massachusetts Institute of Technology's Computer Science and
Artificial Intelligence Laboratory, Rus delivered the inaugural lecture in
Northeastern's Distinguished Speaker Series in Robots.
"Imagine
a world where you're being driven home by your autonomous car," said Rus.
"Your car is connected to your refrigerator, which tells it what
ingredients you need for dinner. The car is also connected to the grocery store, which is run by robots that fill your bags so they are ready when you
drive up. Then you bring the food home to the robot cook and you happily let
your children help in the kitchen even though they make a mess, because the mess
will be taken care of by the cleaning robot."
"I
know this sounds like a futuristic cartoon, but it's not that far off."
While
conceding that many of the innovations she discussed are still in the formative
stages, she enthralled the audience with eye-popping demonstrations of the
early iterations of a variety of futuristic robot applications.
Self-assembling
robots
Oneway to accelerate robot development is to create robots that can build
themselves— and reconfigure themselves into whatever shape is best for
performing the task at hand. While this might sound farfetched, Rus pointed out
that this is the way nature already works, reconfiguring the building blocks of
life into frogs, birds, and alligators. What if we could create a miniature
robot cell that could assemble itself into wide range of tools?
Not
only is this possible, it's already being done.
Rus
showed a video of robot cells created at MIT that can assemble themselves into
different shapes. Granted, these one-centimeter cubes are not nearly small
enough yet, but they do provide a proof of concept. With no human controlling
them, these dice-sized blocks roll across the table and climb atop one another,
assembling themselves into various pre-determined patterns.
Rus
predicted that we will soon be able to create smaller, more sophisticated cells
that can assemble themselves into a snakelike robot that can slither through
small places, then reassemble itself into a slinky that can climb stairs.
Robot
surgery
"What
if I told you that we will be able to use robots to perform surgery with no
incision, no risk of infection, and no pain?" asked Rus. She demonstrated
the concept with a video of simple stomach surgery performed by a tiny robot
inside an artificial stomach.
The
task: every year, 3,500 people swallow button batteries, the little silver
discs that power watches, pacemakers, and hearing aids. These batteries often
get lodged in the stomach and, if they aren't passed through the system
quickly, they become embedded in the stomach lining and have to be surgically
removed.
To
perform the surgery, a robot the size of your pinky fingernail is incased in a
pill made of ice. The pill is swallowed and melts in the stomach, releasing the
robot. The robot then propels itself across the stomach, locates the battery,
and pulls it out of the stomach lining. The patient then swallows a second pill
that contains a robot that delivers medicine to help heal the wound.
Origami
robots
One
of the most promising ways to reduce the cost of robot manufacturing is to develop origami robots that are printed in flat sheets and then
intricately folded into robots that can perform specific tasks.
Because
they are 3-D printed, these robots are inexpensive to manufacture. The biggest
cost is the time spent manually folding the complex designs into a working
robot. So what if these origami robots could fold themselves?
Again,
it's already being done, according to Rus.
Instead
of manufacturing an origami template as a single sheet, it's produced as a
two-ply sheet with one layer made of a static substance like metal and the
other made of a substance that shrinks when heated, like the child's toy
Shrinky Dinks. To determine where the folds will be, you leave thin gaps in the
metal substance wherever you want the two-ply sheet to fold. The angle of the
fold is determined by the width of the gap in the metal.
Once
the design is completed and the two-ply sheet printed, all you have to do is
place the sheet on a heated surface and, voila, it folds itself.
Many
developments underway
Rus
showed robotic models of flying cars, robots that can recycle themselves, and
lightweight robotic muscles made of tiny airbags that inflate and deflate to
mimic muscular contraction. These early-stage muscles can lift three times
their own weight, and Rus said when they are attached to a skeletal system with
joints, the possibilities will be endless.
Rus
also described how developers are making robots more versatile by developing
exoskeletons designed to perform specific tasks. "The robots can put on
and take off these exoskeletons much like a human puts on a coat," said
Russ. One exoskeleton might allow the robot to climb through a rugged
landscape, while others might be for fine motor dexterity or to carry objects
efficiently.
She
also described efforts to create robots that can learn from a human who knows
nothing about computer coding. "Today, you can drive a car without knowing
anything about how the engine works," she said. "And soon, you will
be able to program a robot just as easily."
She
described how robots are being programed to learn by "watching" a
human perform a complex task. The human wears a system of sensors on his arms,
hands, torso, and legs, and these sensors are connected to the robot. As the
person performs the task, of his movements are transmitted to the robot, which is pre-programed memorize how to perform
the jobs. No additional coding is required.
"The
possibilities are endless," said Rus. "And a world with a lot of robots is a world with a lot of fun."
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