A major problem for visually impaired college students is independent campus
navigation. Many universities, such as Utah State University (USU), have no Orientation
and Mobility (O&M) instructors. Thus, visually impaired undergraduates must rely on
their friends, siblings, and even parents to learn their way around a large campus, which
reduces their sense of independence. This paper describes a wearable two-sensor O&M
device for visually impaired USU undergraduates and presents a single subject feasibility
test that estimates how a visually impaired navigator can use the device to learn new
routes on the USU campus.
IESVE Software for Florida Code Compliance Using ASHRAE 90.1-2019
A Wearable Two-Sensor O&M Device for Blind College Students
1. A Wearable Two-Sensor O&M Device for Blind College Students
John Nicholson and Vladimir Kulyukin
Computer Science Assistive Technology Laboratory
Department of Computer Science
Utah State University
Logan, UT 83422-4205
ABSTRACT
A major problem for visually impaired college students is independent campus
navigation. Many universities, such as Utah State University (USU), have no Orientation
and Mobility (O&M) instructors. Thus, visually impaired undergraduates must rely on
their friends, siblings, and even parents to learn their way around a large campus, which
reduces their sense of independence. This paper describes a wearable two-sensor O&M
device for visually impaired USU undergraduates and presents a single subject feasibility
test that estimates how a visually impaired navigator can use the device to learn new
routes on the USU campus.
KEYWORDS
Visual impairment; blindness; assisted navigation; outdoor navigation; GPS; digital
compass
BACKGROUND
Each year USU accepts a few visually impaired students [3]. The most difficult period for
these individuals is the first semester when they do not know the campus and have to rely
on sighted guides, e.g., siblings, friends, classmates, and even parents, to find their way
around. The problem is recurrent in that a blind student must learn new routes every
semester when the student takes a class that meets in a building he or she has never
visited before. It is hoped that the proposed device will be available to the new visually
impaired students through the Disabled Students Resource Center. The students will
check out such a wayfinding device upon arrival, use it until they become comfortable
with the campus, and return it back to the Center. It is important to note that, unlike most
paradigms in assisted navigation, this paradigm does not attempt to create a device
dependency. Instead, the objective is to create a device that is used only temporarily until
its user achieves the required level of navigation independence in a given environment.
HYPOTHESIS
It is hypothesized by the investigators that a wearable system that consists of a small
computational unit, a GPS receiver, a digital compass, a headphone, and a text-to-speech
engine can enable a visually impaired navigator learn new routes independently. This
research is inspired by the findings of the research group at the University of California at
Santa Barbara headed by Loomis and Klatzky that has been doing basic and applied
research on the Personal Guidance System (PGS), a navigation system for the visually
2. impaired [1]. The main differences between the research presented in this paper and the
PGS research are: 1) a novel GPS-based localization method, 2) addition of a digital
compass to the suite of sensors, 3) exclusion of 3D audio for information delivery, and 4)
focus on independent route learning
METHOD
--------------------------------------
Insert Figures 1, 2, and 3 here.
--------------------------------------
The current prototype, called WayFinder, (see Figure 1) is worn as a vest. The system
consists of a GPS unit on one shoulder and a digital compass on the other shoulder. A
computational unit sits in the front on the user’s chest with an attached numeric keyboard
which allows the user to enter commands and respond to prompts from the system. A
PCMCIA wireless card can be inserted on the bottom of the computation unit although it
is not currently used in outdoor environments. The system has headphones which allow
the user to hear the system give commands and prompts. Figure 2 shows the hardware
components of the WayFinder hardware platform in an acrylic container attached to the
vest. Figure 3 shows the hardware architecture.
In outdoor environments, the system relies on a modified use of GPS for localization in
order to increase accuracy [2]. GPS data can also be used to infer directionality but it is
not reliable due to signal drift caused by errors with GPS data. Thus, it can appear that
the latitude and longitude of a user are changing even when the user is standing still. A
digital compass overcomes this by providing reliable direction information. Currently,
the compass is used to orient the user to the proper direction before they begin their route
and then, as the user is moving along a route, it periodically reports the current direction
to the user
When the user desires to go to a new destination, the user first enters the destination into
the system through a small wearable keypad. When the user is ready to start, the system
orients the user using the compass so that the user starts walking in the correct direction.
As the user moves along the desired route the system periodically informs the user of his
or her direction the user or tells the user what action needs to be taken: continue walking
forward, turn left or turn right. When the user reaches the desired destination, the system
gives final instructions such as how far away the door to the building is. The only time
the user actually has to enter information into the system is at the beginning of a walk.
The desired destination is chosen by navigating a voice-based directory of available
destinations.
--------------------------------------
Insert Figure 2 here.
--------------------------------------
In order to see if the device can aid a person in learning new routes, four routes (see
3. Figure 2) were chosen on the Utah State University campus. The routes were the paths a
user would take to get from building to building. When combined, the four routes form a
loop with the user ending up at the start position of route 1 when he finished route 4. The
routes all kept the user on the sidewalk.
The test subject was a visually impaired USU graduate student who is a guide dog
handler. Over each route the system correctly instructed the user when and which
direction to turn, and periodically reported the compass direction to the user Upon arrival
it gave final instructions on how to enter the building. After completing the loop of test
routes once using the Wayfinder, which took approximately 15 minutes, the user was
asked to repeat the loop with out the device.
RESULTS
The subject successfully completed all four routes. After the test was completed, the test
subject stated that route 3 was the most difficult route, because it contained a long
straight path. He noted that one of the buildings he passed by had a furnace which he
could hear during the walk with the Wayfinder. On the walk without the Wayfinder, he
used that furnace noise to time how long he had to walk before turning onto the sidewalk
for the Ag Science destination. Although the test subject did not know the routes in
advance, he was familiar with the area. A true test of the system will require test subjects
who are totally unfamiliar with both the routes and the area. While the user really liked
the functionality of the system and understood that it was just a test bed, he suggested
that the system must be smaller and less conspicuous.
REFERENCES
1.Golledge, R. G., Marston, J. R., Loomis, J. M., & Klatzky, R. L. (2004). Stated
preferences for components of a Personal Guidance System for non-visual navigation.
Journal of Visual Impairment and Blindness, 98(3)
2. Kulyukin, V. and Nicholson, J. (2005). On Overcoming Longitudinal and Latitudinal
Signal Drift in GPS-Based Localization Outdoors. Proceedings of the Rehabilitation
Engineering and Assistive Technology Society of North America (RESNA). Atlanta, GA.
3. E. Lawyer. Utah State Projects Assist the Blind. Utah Statesman, Sept. 26, 2005.
ACKNOWLEDGMENTS
The study was funded, in part, by two Community University Research Initiative (CURI)
grants from the State of Utah (2003-04 and 2004-05) and NSF Grant IIS-0346880. The
authors would like to thank Mr. Sachin Pavithran, a visually impaired training and
development specialist at the USU Center for Persons with Disabilities, for his feedback
on the localization experiments.
4. TABLES AND FIGURES
------------------------
Figure 1. Photograph of the Wayfinder
------------------------
Alternative Text Description for Figure 1.
Figure 1 shows a photograph of the Wayfinder system being worn.
5. ------------------------
Figure 2. Map of Routes
------------------------
Alternative Text Description for Figure 2.
Figure 2 shows the four routes taken and learned by the user during the proof of concept
tests. The four buildings involved in the test were Old Main, Merrill Library, Ray B
West, and Ag Sciences. Route 1 goes east from Old Main to Merrill Library. Route 2
goes west and then south from Merrill Library to Ray B West. Route 3 goes north, then
east, and then north again from Ray B West to Ag Sciences. Route 4 goes south and then
west from Ag Sciences to Old Main.