Can someone explain polarization states to me in really simple terms?

In summary, if you have an equation that describes the direction of polarized light, but you don't know what the individual components contribute to that meaning, then you can use a mathematical model to calculate what the individual components might be. However, if you only have an equation that describes the direction of polarized light, then you can't use that equation to determine what the individual components are.
  • #1
iamsolost22
5
0
Let's say I have an equation E=iE0cos(kz-wt)-jE0cos(kz-wt), how do I look at this and know, this is linearly polarized? or what if it changes and the kz is negative? or its a sin function with with (wt-kz-pi/4) in it. I just don't understand what this equation is supposed to be telling me and what all the components contribute to that meaning.
 
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  • #2
Welcome to PF iamsolost22!

You'll notice that the x- and y-components of the E field have the same phase. As a result, they'll vary with time together, and the ratio of their magnitudes will never change. Therefore, the overall direction of the E-vector won't change. That's how you can tell just by looking at it that the vector is linearly polarized and that it will always point along the same line.

If the x- and y-components did not have the same phase, then they would vary out of step with each other. The ratio of the x- and y-components would therefore vary with time, and as a result, the vector would change direction with time. This would correspond to a rotation in the plane of polarization. The vector is not linearly polarized in this case.
 
  • #3
cepheid said:
Welcome to PF iamsolost22!

You'll notice that the x- and y-components of the E field have the same phase. As a result, they'll vary with time together, and the ratio of their magnitudes will never change. Therefore, the overall direction of the E-vector won't change. That's how you can tell just by looking at it that the vector is linearly polarized and that it will always point along the same line.

If the x- and y-components did not have the same phase, then they would vary out of step with each other. The ratio of the x- and y-components would therefore vary with time, and as a result, the vector would change direction with time. This would correspond to a rotation in the plane of polarization. The vector is not linearly polarized in this case.

ok so if i had an equation like E=iE0sin(wt-kz)+ jE0sin(wt-kz-pi/4), i should be dividing one by the other to get the ratio of x to y and that will tell me if it is circular, elliptical or linearly polarized? so in that case it varies by a pi/4 component which would make it, elliptical? is there a graphical way to look at this, so i get what the waves look like from wikipedia and such but i don't understand how that translates to linear, versus circular since none of the pics look down the propagation axis.
 
  • #4
and what difference does it make if it is negative? it says its direction can be counter clockwise or clockwise on the wiki, is negative pi/4 a counterclockwise direction then
 
  • #5
iamsolost22 said:
ok so if i had an equation like E=iE0sin(wt-kz)+ jE0sin(wt-kz-pi/4), i should be dividing one by the other to get the ratio of x to y and that will tell me if it is circular, elliptical or linearly polarized?

No, I wasn't saying that you explicitly had to divide them. I was just saying that you could tell at a glance whether or not it was linearly polarized based on whether the ratio of the magnitudes of the components was varying with time or not.

iamsolost22 said:
so in that case it varies by a pi/4 component which would make it, elliptical? is there a graphical way to look at this, so i get what the waves look like from wikipedia and such but i don't understand how that translates to linear, versus circular since none of the pics look down the propagation axis.

A quick Google image search of "light polarization" revealed many potentially helpful images. For circular polarization, it's clear that the two vector components have to have the same magnitude and be out of phase with each other by pi/2, since one would then be described by a cosine wave, and the other by a sine wave, and hence the total E-vector would clearly trace out a circle in the plane of polarization. For a more rigorous treatment of polarization that explains how you can tell the difference polarization states apart from each other mathematically I also find this set of optics lecture notes helpful:

http://atomoptics.uoregon.edu/~dsteck/teaching/optics/

Click on the link to the full PDF on that page and go to Chapter 8. Note: the author is making this freely available. He explains how elliptical polarization is the most general type, and all of the others are special cases of it.
 

1. What is polarization?

Polarization is the direction of oscillation of an electromagnetic wave as it travels through space. It can be thought of as the orientation of the wave's electric field.

2. What are polarization states?

Polarization states refer to the different orientations of polarization that an electromagnetic wave can have. This includes vertical, horizontal, and diagonal orientations.

3. How do polarization states affect light?

Polarization states affect how light interacts with certain materials and how it is transmitted or reflected. For example, polarized sunglasses use the principle of polarization to block glare and reduce eye strain.

4. Can you give an example of polarization in everyday life?

Sure, a common example of polarization in everyday life is the use of polarized sunglasses. They are designed to block horizontally polarized light, which is often reflected off of surfaces like water or snow, reducing glare and improving visibility.

5. How is polarization used in technology?

Polarization is used in various technologies, such as LCD screens, 3D glasses, and satellite communications. In LCD screens, a polarizing filter is used to control the orientation of light passing through, allowing for the display of images and videos. In 3D glasses, different polarization states are used for each eye to create the illusion of depth. In satellite communications, polarized signals are used to prevent interference between different channels.

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