Dolphin-like laser 'chirps' could
boost outdoor optical wireless
performance
Posted on Wednesday, October 27 @
13:00:00 CDT by bjs
| |
 Multi-rate, ultra-short laser pulses -- with
wave forms shaped like dolphin chirps -- offer a new approach
to help optical wireless signals penetrate clouds, fog and
other adverse weather conditions, say Penn State engineers.
The new approach could help bring optical bandwidth, capable
of carrying huge amounts of information, to applications
ranging from wireless communication between air and ground
vehicles on the battlefield to short links between college
campus buildings to metropolitan area networks that connect
all the buildings in a city.
From Penn
State:
Multi-rate laser pulses could boost outdoor
optical wireless performance
Multi-rate,
ultra-short laser pulses -- with wave forms shaped like
dolphin chirps -- offer a new approach to help optical
wireless signals penetrate clouds, fog and other adverse
weather conditions, say Penn State engineers.
The new
approach could help bring optical bandwidth, capable of
carrying huge amounts of information, to applications ranging
from wireless communication between air and ground vehicles on
the battlefield to short links between college campus
buildings to metropolitan area networks that connect all the
buildings in a city.
Dr. Mohsen Kavehrad, the W. L.
Weiss professor of electrical engineering and director of the
Center for Information and Communications Technology Research,
leads the study. He says, ''The multi-rate approach offers
many advantages. For example, lower rate signals can get
through clouds or fog when high rate signals can't. By sending
the same message at several different rates, one of them can
probably get through.''
Rather than slowing
communication down, the multi-rate approach has been shown in
tests to achieve an average bit rate higher than conventional
optical wireless links operating at 2.5 Gbps as well as
providing an increased level of communication reliability by
maintaining a minimum of one active link throughout channel
conditions, he adds.
Kavehrad outlined his team's new
approach at the Optics East 2004 Conference in Philadelphia,
Oct. 27, in a paper, ''Ultra-short Pulsed FSO Communications
System with Wavelet Fractal Modulation.'' He will also
describe the system at the IEEE MILCOM conference in Monterey,
California, on Nov. 1. His co-author is Belal Hamzeh, doctoral
candidate in electrical engineering.
In optical
wireless systems, also known as free-space optics (FSO),
voice, video and/or data information is carried on
line-of-sight, point-to-point laser beams. Outdoor FSO systems
have been in use for over 30 years but are hampered by weather
and other obstructions that prevent the transmitter and
receiver from ''seeing'' each other.
Kavehrad explains
that clouds and fog often clear abruptly providing brief
windows for transmission, making pulsed delivery better suited
to FSO. The new Penn State approach embeds data in ultra-short
pulses of laser light, shaped via fractal modulation as
wavelets, and then transmits the wavelets at various
rates.
Belal says the wavelets are easy to generate.
''We use holography to generate and separate the wavelets. You
just generate the mother wavelet and then the others can be
generated as a fraction of the transmission bit rate of the
mother. They can all co-exist in the channel without
interference,'' he notes.
The wavelets used by the Penn
State team are Meyer's Type which look like dolphin chirps.
The wavelets minimize bandwidth waste and the ultra-short
pulses are less likely to interact with rain or fog that could
degrade the signal.
The researchers note that their
proposed system ensures on-the-fly operation without the need
for significant electronic processing. The project is
supported by the Air Force Research
Laboratory.
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