:max_bytes(150000):strip_icc():format(webp)/GettyImages-89936891-581e4e153df78cc2e8829857.jpg) |
| A mobile Doppler radar truck participating in Project Vortex 2 scans a tornado-producing storm in western Nebraska. |
Doppler Radar
How Does Doppler Radar Work?
Doppler Radar
for Radar Guns and Weather
Andrew Zimmerman Jones
One discovery that is used in
a variety of ways is the Doppler effect, even though at first glance the
scientific discovery would seem to be rather impractical.
The Doppler effect is all
about waves, the things that produce those waves (sources), and the things that
receive those waves (observers).
It basically says that if the
source and observer are moving relative to each other, then the frequency of
the wave will be different for the two of them.
This means that it's a form of
scientific relativity.
There are actually two main
areas where this idea has been leveraged into a practical outcome, and both
have ended up with the handle of "Doppler radar."
Technically, Doppler radar is
what is used by police officer "radar guns" to determine the speed of
a motor vehicle.
Another form is the
Pulse-Doppler radar which is used to track the speed of weather precipitation,
and usually, people know the term from it being used in this context during
weather reports.
Doppler Radar: Police Radar Gun
Doppler radar works by sending
a beam of electromagnetic radiation waves, tuned to a
precise frequency, at a moving object.
(You can use Doppler radar on
a stationary object, of course, but it's fairly uninteresting unless the target
is moving.)
When the electromagnetic
radiation wave hits the moving object, it "bounces" back toward the
source, which also contains a receiver as well as the original transmitter.
However, since the wave
reflected off of the moving object, the wave is shifted as outlined by
the relativistic Doppler effect.
Basically, the wave that is
coming back toward the radar gun is treated as an entirely new wave, as if it
were emitted by the target it bounced off of.
The target is basically acting
as a new source for this new wave.
When it is received at the
gun, this wave has a frequency different from the frequency when it was
originally sent toward the target.
Since the electromagnetic radiation was at a
precise frequency when sent out and is at a new frequency upon its return, this
can be used to calculate the velocity, v, of the
target.
Pulse-Doppler Radar: Weather Doppler Radar
When watching the weather, it
is this system which allows for the swirling depictions of weather patterns
and, more importantly, detailed analysis of their movement.
The Pulse-Doppler radar system
allows not only the determination of linear velocity, as in the case of the
radar gun, but also allows for the calculation of radial velocities.
It does this by sending pulses
instead of beams of radiation. The shift not only in frequency but also in
carrier cycles allows one to determine these radial velocities.
In order to achieve this,
careful control of the radar system is required. The system has to be in a
coherent state which allows for stability of the phases of the radiation
pulses.
One drawback to this is that
there is a maximum speed above which the Pulse-Doppler system cannot measure
radial velocity.
To understand this, consider a
situation where the measurement causes the phase of the pulse to shift by 400
degrees.
Mathematically, this is
identical to a shift of 40 degrees, because it has gone through an entire cycle
(a full 360 degrees).
Speeds causing shifts such as
this are called the "blind speed."
It is a function of the pulse
repetition frequency of the signal, so by altering this signal, meteorologists
can prevent this to some degree.
Edited by Anne Marie
Helmenstine, Ph.D.
Andrew
Zimmerman Jones
Math
and Physics Expert
Education
M.S.,
Mathematics Education, Indiana University
B.A.,
Physics, Wabash College
Introduction
Academic
researcher, educator, and writer with 23 years of experience in
physical sciences
Works
at Indiana Department of Education as senior assessment specialist in
mathematics
Co-author
of String Theory For Dummies
Member
of the National Association of Science Writers
Experience
Andrew
Zimmerman Jones is a former writer for ThoughtCo who contributed nearly 200
articles for more than 10 years. His topics ranged from
the definition of energy to vector mathematics. Andrew is a
dedicated educator; and he uses his background in the physical sciences,
educational assessment, writing, and communications to advance that mission.
Andrew
is co-author of String Theory For Dummies, which discusses the basic
concepts of this controversial approach. String theory tries
to explain certain phenomena that are not currently explainable under the
standard quantum physics model.
Since
2018, Andrew has worked at the Indiana Department of Education as a senior
assessment specialist in mathematics; prior to which he served as a senior
assessment editor at CTB/McGraw Hill for 10 years. In addition, Andrew was a
researcher at Indiana University's Cyclotron Facility. He is a member
of the National Association of Science Writers.
Education
Andrew
Zimmerman Jones received an M.S. in Mathematics Education from Indiana
University–Purdue and a B.A. in Physics from Wabash College.
Awards
and Publications
String Theory For Dummies (Wiley–For Dummies Series,
2009)
Harold
Q. Fuller Prize in Physics (Wabash College, 1998)
ThoughtCo
and Dotdash
ThoughtCo is a premier
reference site focusing on expert-created education content. We are one of the
top-10 information sites in the world as rated by comScore, a leading Internet
measurement company. Every month, more than 13 million readers seek answers to
their questions on ThoughtCo.
For
more than 20 years, Dotdash brands have been helping people find answers,
solve problems, and get inspired. We are one of the top-20 largest content
publishers on the Internet according to comScore, and reach more than 30% of
the U.S. population monthly. Our brands collectively have won more than 20
industry awards in the last year alone, and recently Dotdash was named
Publisher of the Year by Digiday, a leading industry publication.
No comments:
Post a Comment