"What is
Physics Good For?"
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page. Please respond before 9 AM, Monday, March
26th, 2001.
Magnets, Coils,...
Loudspeakers
If you like to listen to music, physics is good for
that too. In recent weeks, we have studied magnetic
fields and forces, and we are about to start
studying alternating current circuits. All of these
topics are needed to understand the operation of a
loudspeaker.
We have recently learned that magnetic fields
are produced by current flowing in wires, and that
wires carrying current feel magnetic forces. I have
also written a bit about magnetic materials.
However, the connection may still not be quite
clear. This page will attempt to clear up the
difficulty, and turn to an extremely popular
application: the loudspeaker. In a loudspeaker,
current flowing in wires puts a force on a piece of
magnetic material. That magnetic material moves in
response. In turn, the magnet pushes a paper or
plastic cone, and the cone pushes the air. The
result is sound, perhaps music.
First, let's consider how the force on a magnet
arises from a magnetic field. For the purposes of
this discussion, we will consider each atom in the
magnet to be composed of a positive nucleus being
orbited by a single electron. Of course, most atoms
have more than one electron, and the idea of
"orbits" is not really an accurate picture of the
electron's behavior. However, to describe these
things properly (and learn more about magnetism,
superconductivity, etc.) we really would need to
learn a little quantum mechanics. If you are
interested, take Phys 342, that's where the fun
really starts.
If these model atoms are placed in a
uniform external magnetic field they will feel
a torque but they will feel no net
force The figure to the left shows this
situation. In this view, the motion of the electron
is into the page at the lower left, out of the page
in the upper right, and in the plane of the page,
down and to the left as it passes "in front" of the
atom. Using the right hand rule gives the forces
shown (remember the electron has a negative
charge!). There would also be forces out of the
page in front and into the page
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An atom (or any current loop) feels a
torque that tends to align its magnetic moment
with an external field. |
in back of this picture. As you can see, the net
force will be zero, however, there will be a net
torque trying to force the electron's orbit to be
perpendicular with the external magnetic field.
Here is an important point: Consider the
electron to be a current loop. Thus, it generates a
small magnetic field of its own. As drawn in the
figure, the magnetic field at the center of the
electron's orbit will be up and to the left (again,
remember the electron is negative!). If the torque
succeeds in rotating the electron's orbit, the
magnetic field of the orbit will be aligned with
the external magnetic field.
This explains how an unmagnetized piece of
magnetic material becomes magnetically polarized
(magnetized) by an external magnetic field.
However, it does not explain the force that
is felt. To understand this, we must recall that
the field of a magnet is not uniform. It
looks more like a dipole field.
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An atom (or any current loop) feels a force
that tends to pull it towards regions of higher
field |
Note that the field near the poles (where we get
strong attractive forces) is not uniform. Rather,
it gets stronger (field lines closer together) as
we approach the magnet. It is this gradient
in the magnetic field that produces the attractive
force. To understand this, look at the figure to
the right. In this view, the electron comes out of
the page on the right and goes into the page on the
left. It crosses from right to left in front of the
nucleus. Notice that the net force is not zero in
this picture. Rather, the atom feels a force
dragging it towards the region of higher magnetic
field. If all of the atoms in a solid behave this
way, we feel it as a net force pulling the solid
into the magnetic field.
Now, finally, we can have a look at the guts of
a loudspeaker. Here is a simplified cross
section.
When current is passed through the coil it
produces a magnetic field that is constant in
magnitude inside and looks like that of a bar
magnet outside (see the description of long,
straight solenoids in your text).
If the current changes in time (like the signal
from from your amplifier does) then the field will
change in time with it. If the current is a sine
wave, for instance, then the field will also be a
sine wave. In this case, the magnet is attracted in
or pushed out as the signal oscillates. In most
speakers, it is the coil and cone that move while
the magnet stays fixed. The force on the coil is
equal and opposite to the force on the magnet.
Whose third law is this?
Music is not a simple sine wave, but it can be
considered as a whole bunch of sine waves added to
one another (The method of describing a complicated
signal in terms of sines and cosines is called
Fourier analysis, but we will not go into that
here.) Simple loudspeakers (such as those in cheap
car stereos, and the speakers that are built into
most computers consist of a single speaker.
However,even moderately priced home speakers have
more than one "speaker" inside. The different
speakers are optimized to perform best for
different frequency ranges. Usually, the speaker
that handles the high frequencies is called a
"tweeter" and the one that handles lower
frequencies is called a "woofer". In three-way
systems there is also a "midrange", and more
complex systems may include "'supertweeters" and
"subwoofers."
How
does each of these speakers know what part of the
signal to reproduce? Inside the loadspeaker, there
is a set of circuitry called a "crossover network"
that divides the signal up into frequency ranges,
and sends the parts of the signal to each of the
speakers as needed. The figure to the right shows a
simplified version of a loadspeaker system with
three speakers and a simple crossover. The
capacitor at the top of the crossover filters out
all but the highest frequencies (recall that
XC = 1/C).
Thus, the tweeter only responds to the high
frequencies in the music. The inductor
(XL = L) at
the bottom does the same job for the woofer,
passing only the low frequencies. The
inductor-capacitor pair in the middle passes only
the medium frequencies to the midrange.
You can get a lot more information about this
subject on the internet. Here are a few search
engines
1. Alta Vista
2.
Google
3. Northern Light
4. Ask Jeeves
5. Infoseek
And here are a few good links to get you
started.
1. 2. 3.
This site is made possible by
funding from the National Science Foundation
(DUE-9981111).
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