News - April 5, 2010
Braille Displays Promise to Deliver the Web to the Blind
North Carolina State University researchers take the first steps toward
making an affordable and more dynamic Braille display
By
Larry Greenemeier
The Web's wealth of information would lose some of its luster if you read it
only one line at a time. Yet this is exactly how blind and other
vision-impaired people today must experience the Web when they use
electronic Braille displays connected to their computers.
Braille displays use electromechanically controlled pins, as opposed to the
lights in a conventional computer monitor, to convey information. Here is
how: Software gathers a Web page's content from the computer's operating
system, converts the words and images into a digital version of Braille and
then represents that via a touchable row of finger-sized rectangular cells
lined up side by side like dominoes. Each cell has six or eight small holes
through which rounded pins can extend and retract with the help of
piezoelectric ceramic actuators to represent various Braille characters.
Each time a person reads the row of Braille with his fingers (left to
right), the pin configurations refresh to represent the next line of a Web
page's text, and so on.
Breaking Braille barriers Efforts to improve Web pages translated into
Braille have progressed slowly because of the cost and complexity of Braille
displays, but a team of North Carolina State University researchers in
Raleigh has taken the first steps toward developing a device that would
allow the blind to take better advantage of the Web and other computer
applications. Instead of presenting electronic content one line at a time,
this display would translate words and images into tactile displays
consisting of up to 25 rows, each with 40 cells side by side. Braille
readers would have multiple lines of text and numbers at their fingertips,
enabling them to backtrack and review content more easily. Another
possibility might be to present in Braille equations and other information
that take up more than one line at a time.
"It's difficult to achieve any spatial recognition with just a single line,"
says Neil Di Spigna, a research assistant professor in N.C. State's
Department of Electrical and Computer Engineering who is working on the
project.
The use of piezoelectric ceramic to make a Braille display with multiple
rows would make already pricey displays even more expensive-low-end models
with a single row already cost upwards of $1,000. In addition, the amount of
energy needed to power multiple rows would make these displays bigger,
heavier and less portable.
Touch and go The N.C. State researchers are experimenting with two different
approaches they hope will cut the costs and energy requirements of Braille
displays in the future, and presented their latest research at the
International Conference on Electroactive Polymer Actuators and Devices in
San Diego last month.
The first approach would rely on hydraulic pressure to raise and lower each
of the pins in a cell. In this scenario, each pin would sit in a
fluid-filled plastic case. A window would be cut into the case and covered
with a polyvinylidene fluoride (PVDF) film. When electricity is applied to
the cell the PVDF would bend in and squeeze the case through that window,
raising the level of the fluid and the pin along with it. The researchers
say they have demonstrated a proof-of-concept prototype that, when less than
1,000 volts were applied, got the case to contract and push a fluid
consisting of deionized water and food dye up so that a pin would rise more
than 0.5 millimeters-the standard height of a Braille dot-in less than 100
milliseconds (initial experiments have been done without a pin in the case).
This is the kind of speed performance a Braille user would expect, says
Peichun Yang, a postdoctoral research associate in N.C. State's Department
of Electrical and Computer Engineering who is also working on the project.
Yang, who is blind, adds that he and his colleagues, including project
director Paul Franzon, have gotten the fluid to move in 30 milliseconds in
some trials. Their next step is to create a latching mechanism within the
case that would hold a pin in place until it needs to be lowered.
The second approach being considered would place each pin in a cylindrical
silicon tube that raises the pin up when the tube is filled with a
conductive solution of calcium chloride and 8.75 kilovolts are applied.
The standard piezoelectric approach to making a Braille display costs about
$35 per cell, according to Yang, who adds that this cost needs to be brought
down to $5 per cell for the displays to be affordable to a greater number of
consumers. The researchers say that more widespread adoption of Braille
displays will depend largely on cost, which was an important factor behind
their research.
Currently, Freedom Scientific, Inc., in Saint Petersburg, Fla., makes
several different computer Braille displays whose cells are laid out in the
standard single-row configuration. The company's portable PAC Mate Braille
display is offered in a single row consisting of 20 or 40 cells, with
displays costing about $1,600 and $3,600, respectively. Freedom Scientific's
larger Focus displays include 40- and 80-cell single-row models, which cost
about $3,900 and $7,800, respectively.
Other approaches The National Institute of Standards and Technology (NIST)
recognized the cost problem a decade ago, when an 80-cell Braille display
cost about $15,000. Since then, NIST has for several years been working on a
display with a much different design, putting the Braille text on the
outside of a spinning cylinder like the tread on a tire (pdf). The actuators
that move the pins in and out are located inside the cylinder. Instead of
moving fingers over a motionless line of text, the NIST design has the user
put one or more fingers against the wheel, with the Braille text moving
underneath the finger, producing a sensation of motion, which the agency
claimed provided stimulus for the sensors in the fingertips and allowed the
user to construct a mental model of the geometric layout of the text. The
user could also adjust the speed of the wheel's rotation.
Speech synthesizer software that can read the contents of the Web or other
computer text to the blind is an alternative and has the advantage of being
easier to learn than Braille. Still, as NIST notes in its research, Braille
has other advantages, enabling "high-precision communication" and the
ability to read in noisy surroundings.
Speech synthesizers do have a role in helping the blind experience the Web,
Yang agrees, but the ability to read Braille is essential. "Reading Braille
is still very important for [blind people] who wish to work-90 percent of
blind people who hold a job are able to read Braille," he says, adding that
synthesizer technology is one of the reasons why only 10 percent of blind
children are learning to read Braille.
N.C. State's work is still in its early days, so do not expect to see their
Braille display technology at the local computer story in the immediate
future. It could take the researchers as long as a year just to develop a
reliable latching system to keep the pins in place. Only then would they be
able to make an actual Braille display. After that, it could be at least
four years to make a commercial product, Di Spigna says.
http://www.scientificamerican.com/article.cfm?id=braille-display-web&print=true
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