This nanoparticle film could guide surgeons' tools and help robots grip.
By
Researchers
have created a thin-film tactile sensor that, in some ways, is as
sensitive as the human finger. When pressed against a textured object,
the film creates a topographical map of the surface, by sending out
both an electrical signal and a visual signal that can be read with a
small camera. The spatial resolution of these "maps" is as good as that
achieved by human touch.
Via MIT Technology Review
Saraf has demonstrated the sensor on a glass backing, but he says the film could also be made on flexible polymer sheets. Such flexibility would be necessary to wrap the sensor around a robot's "finger" or the tube of an endoscope (a camera inserted through a small cut that allows surgeons to operate inside the body). Saraf says such an endoscope could take concurrent visual and tactile images, helping surgeons "feel" which tissues the scope is up against.
Srinivasan
says an ideal sensor "essentially has to be what skin is: flexible,
with the ability to sense dynamically and with high spatial resolution,
and physically robust -- it shouldn't break, it shouldn't wear out."
Human skin obtains highly sensitive tactile readings by having sensors
with different strengths. Some cells are good at sensing vibration or
movement over time (which is essential for feeling something slipping
from your grip); other cells accurately sense a point of pressure
smaller than a micrometer.High touch sensitivity "is
extremely important" for robotics, says Robert Platt, a robotics
engineer at the NASA-Johnson Space Center who works on the hands for Robonaut,
a humanoid robot. To perform the most basic human tasks -- dexterous
grasping, walking on two legs, climbing, even crawling -- robots "need
to be cognizant of and controlling the forces they're applying," he
says. To pick up a glass of water, for example, a robot needs to
dynamically sense the forces exerted by its "hand." Such a task
requires high sensitivity -- not only being able to feel where on its
fingers a stress has been applied, but also in what direction that
force is moving. This information can inform the robot whether an
object is slipping or not, for example. The high spatial
sensitivity of Saraf's sensor would not be enough to help a robot hold
a glass of water, though, because the sensor can't tell the direction
of pressure. Further research will reveal whether or not nanoparticle
layers can sense this kind of tactile information, Saraf says. For now,
though, it is "a promising approach," says NASA's Platt. The sensor was built by Ravi F. Saraf,
professor of chemical engineering at the University of Nebraska, who
hopes it will be used to improve minimally invasive surgeries in which
physicians rely on endoscopes; it could also help robots grip objects
by allowing them to "feel" an object with great sensitivity. Saraf
likes to demonstrate the sensor by creating "stress images" of a penny.
In the images, Lincoln's portrait -- large ears, heavy brow, and even
the folds in his jacket -- are clearly visible. [For an example of a "tactile" image taken using this nanoparticle film, click here.] Indeed,
a tactile sensor comparable to human skin is the holy grail of
robotics, haptics, and sensing research, says Mandayam A. Srinivasan,
senior research scientist in MIT's mechanical engineering department
and founder of the Touch Lab.
The thin film sensor does not have the same robustness, flexibility, or
ability to sense temperature as the human finger. But it's a big step
forward in spatial resolution. "We have all been trying to get
high-resolution tactile arrays," says Srinivasan; "this one is an order
of magnitude better." Saraf says the sensor has a high
enough resolution (40 micrometers horizontally and about 5 micrometers
vertically) to "feel" single cells, and therefore could help surgeons
find the perimeter of a tumor during surgical procedures. Cancer cells
-- in particular, breast cancer cells -- have levels of pressure that
are different from normal cells, and should feel "harder" to Saraf's
sensor. The 100-nanometer-thick film is built on an
electrode-coated glass backing. On top of the glass is the heart of the
sensor: five alternating layers of gold and cadmium sulfite
nanoparticles, separated from each other by polymer sheets. The device
is topped off with an electrode-coated, flexible plastic sheet. Because
the nanoparticles self-assemble, it should be relatively cheap to make
large swaths of the film. "It's just dip and dry," Saraf says. When
the plastic covering the sensor is pressed, the nanoparticle layers
move closer to one another, allowing a measurable electrical current to
flow. The sensor also sends a signal using light. When electrons hop
between the nanoparticle layers, the cadmium sulfite nanoparticles
glow. This light is picked up by a small camera on the other side of
the glass. Both the electrical current and light are proportional to
the pressure on the sensor. When recording with the camera, the
nanofilm can take about 5-10 readings per second; when recording the
electrical current, it can take about 20-50, says Saraf.
Recent Comments