Two beams are better than one
Meet the optical 'it couple' helping to speed up and secure wireless communications
Date:
October 21, 2021
Source:
University of Southern California
Summary:
History's greatest couples rely on communication to make them
so strong their power cannot be denied. But that's not just true
for people, it's also true for lasers. According to new research
from the USC Viterbi School of Engineering, adding two lasers
together as a sort of optical 'it couple' promises to make wireless
communications faster and more secure than ever before.
FULL STORY ==========================================================================
Han and Leia. George and Amal. Kermit and Miss Piggy. Gomez and Morticia.
History's greatest couples rely on communication to make them so strong
their power cannot be denied.
==========================================================================
But that's not just true for people (or Muppets), it's also true for
lasers.
According to new research from the USC Viterbi School of Engineering,
recently published in Nature Photonics, adding two lasers together as a
sort of optical "it couple" promises to make wireless communications
faster and more secure than ever before. But first, a little
background. Most laser-based communications -- think fiber optics,
commonly used for things like high-speed internet -- is transmitted in
the form of a laser (optical) beam traveling through a cable. Optical communications is exceptionally fast but is limited by the fact that
it must travel through physical cables. Bringing the high- capacity capabilities of lasers to untethered and roving applications -- such as
to airplanes, drones, submarines, and satellites -- is truly exciting
and potentially game-changing.
The USC Viterbi researchers have gotten us one step closer to that
feat by focusing on something called Free Space Optical Communication
(FSOC). This is no small feat, and it is a challenge researchers have
been working on for some time. One major roadblock has been something
called "atmospheric turbulence." As a single optical laser beam carrying information travels through the air, it experiences natural turbulence,
much like a plane does. Wind and temperature changes in the atmosphere
around it cause the beam to become less stable. Our inability to control
that turbulence is what has prevented FSOC from advancing in performance similar to radio and optical fiber systems. Leaving us stuck with slower
old radio waves for most wireless communication.
"While FSOC has been around a while, it has been a fundamental challenge
to efficiently recover information from an optical beam that has been
affected by atmospheric turbulence," said Runzhou Zhang, the lead author
and a Ph.D.
student at USC Viterbi's Optical Communications Laboratory in the Ming
Hsieh Department of Electrical and Computer Engineering.
The researchers made an advance to solving this problem by sending
a second laser beam (called a "pilot" beam) traveling along with the
first to act as a partner. Traveling as a couple, the two beams are sent through the same air, experience the same turbulence, and have the same distortion. If only one beam is sent, the receiver must calculate all
the distortion the beam experienced along the way before it can decode
the data. This severely limits the system's performance.
But, when the pilot beam travels alongside the original beam, the
distortion is automatically removed. Like Kermit duetting "Rainbow
Connection" with Miss Piggy, the information in that beam arrives at its destination clear, crisp and easy to understand. From an engineering perspective, this accomplishment is no small feat. "The problem with
radio waves, our current best bet for most wireless communication, is
that it is much slower in data rate and much less secure than optical communications," said Alan Willner, team lead on the paper and USC
Viterbi professor of electrical and computer engineering. "With our new approach, we are one step closer to mitigating turbulence in high-capacity optical links." Perhaps most impressively, the researchers did not
solve this problem with a new device or material. They simply looked
at the physics and changed their perspective. "We used the underlying
physics of a well-known device called a photo detector, usually used
for detecting intensity of light, and realized it could be used in a
new way to make an advance towards solving the turbulence problem for
laser communication systems," said Zhang.
Think about it this way: When Kermit and Miss Piggy sing their song,
both their voices get distorted through the air in a similar way. That
makes sense; they're standing right next to each other, and their sound
is traveling through the same atmosphere. What this photo detector
does is turn the distortion of Kermit's voice into the opposite of the distortion for Miss Piggy's voice. Now, when they are mixed back together,
the distortion is automatically canceled in both voices and we hear the
song clearly and crisply.
With this newly realized application of physics, the team plans to
continue exploring how to make the performance even better. "We hope
that our approach will one day enable higher-performance and secure
wireless links," said Willner. Such links may be used for anything from high-resolution imaging to high-performance computing.
========================================================================== Story Source: Materials provided by
University_of_Southern_California. Original written by Ben Paul. Note:
Content may be edited for style and length.
========================================================================== Journal Reference:
1. Runzhou Zhang, Nanzhe Hu, Huibin Zhou, Kaiheng Zou, Xinzhou Su, Yiyu
Zhou, Haoqian Song, Kai Pang, Hao Song, Amir Minoofar, Zhe
Zhao, Cong Liu, Karapet Manukyan, Ahmed Almaiman, Brittany Lynn,
Robert W. Boyd, Moshe Tur, Alan E. Willner. Turbulence-resilient
pilot-assisted self- coherent free-space optical communications
using automatic optoelectronic mixing of many modes. Nature
Photonics, 2021; 15 (10): 743 DOI: 10.1038/ s41566-021-00877-w ==========================================================================
Link to news story:
https://www.sciencedaily.com/releases/2021/10/211021121055.htm
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