- #1
Watsonb2
- 5
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Hey all,
I'm taking a physics class dealing with harmonic motion and wave motion, and the last homework assignment of the quarter was given a bit late (i.e. after we began to cover extraneous lectures that are abstract and challenging), so I'm finding it hard to get back into the swing of things for the following problems. *Unfortunately, I'm away from both my book and the prof. so I don't have the luxury of consulting either for help at the moment...
As per the spirit of the forum, I'm not looking for answers, merely pointers on what I should go back and look over in order to get started...
1) Malus' Law, insofar as it pertains to systems of two or three polarizers. The prof went over this in class, but I can't seem to find the necessary formula to deal with problem that he's given. Does anyone know how this theorem applies when a vertical polarizer and a second of 60 degrees and a third of 45 degrees is placed into a light's path?
2) The next question deals with linear polarization and our having to determine the equation for the electric and magnetic fields in a vacuum. For the life of me, I can't see how I'm supposed to start as I only remember him talking about actual polarizers, not their respective graphs in the 3D plane. The question specifically asks me about the radiation being polarized in the y-z plane at either 0 or 45 degrees. Any thoughts on the formula I should use to solve this problem?
3) In dealing with a Double Slit Interference apparatus, how do I "design" it so that the central diffraction peak contains 17 fringes? For the problem, I have to assume that the first diffraction minimum occurs at; first, an interference minimum, and second and interference maximum. These problems gave me trouble at the best of times so any help you can offer would be great...
*See above
1) The basis for Malus' Law is: Polarized Intensity = Initial Intensity x Cos^2(The angular deviation from the incident angle).
Do I simply substitute the angles I'm given if I need to find the intensity of the transmitted light, I, in terms of the initially unpolarized light (Io)?
2) This one has me stumped as I don't even know where I should begin equation-wise, unless I simply look at the trigonometric curves that already define the E and B fields in the 3D plane...
3) I'm assuming that for this one, I definitely need to think of my m as being 17, to make sure I include all of the interference fringes. Since I need both a minimum and a maximum, do I also need to consider both: m(wavelength) and (m+1/2)(wavelength) as per the definition for an interference min and max?
Hope you all can provide a bit of insight, as all of this new information is a bit overwhelming when you're first introduced to it...
Thanks,
B
I'm taking a physics class dealing with harmonic motion and wave motion, and the last homework assignment of the quarter was given a bit late (i.e. after we began to cover extraneous lectures that are abstract and challenging), so I'm finding it hard to get back into the swing of things for the following problems. *Unfortunately, I'm away from both my book and the prof. so I don't have the luxury of consulting either for help at the moment...
As per the spirit of the forum, I'm not looking for answers, merely pointers on what I should go back and look over in order to get started...
Homework Statement
1) Malus' Law, insofar as it pertains to systems of two or three polarizers. The prof went over this in class, but I can't seem to find the necessary formula to deal with problem that he's given. Does anyone know how this theorem applies when a vertical polarizer and a second of 60 degrees and a third of 45 degrees is placed into a light's path?
2) The next question deals with linear polarization and our having to determine the equation for the electric and magnetic fields in a vacuum. For the life of me, I can't see how I'm supposed to start as I only remember him talking about actual polarizers, not their respective graphs in the 3D plane. The question specifically asks me about the radiation being polarized in the y-z plane at either 0 or 45 degrees. Any thoughts on the formula I should use to solve this problem?
3) In dealing with a Double Slit Interference apparatus, how do I "design" it so that the central diffraction peak contains 17 fringes? For the problem, I have to assume that the first diffraction minimum occurs at; first, an interference minimum, and second and interference maximum. These problems gave me trouble at the best of times so any help you can offer would be great...
Homework Equations
*See above
The Attempt at a Solution
1) The basis for Malus' Law is: Polarized Intensity = Initial Intensity x Cos^2(The angular deviation from the incident angle).
Do I simply substitute the angles I'm given if I need to find the intensity of the transmitted light, I, in terms of the initially unpolarized light (Io)?
2) This one has me stumped as I don't even know where I should begin equation-wise, unless I simply look at the trigonometric curves that already define the E and B fields in the 3D plane...
3) I'm assuming that for this one, I definitely need to think of my m as being 17, to make sure I include all of the interference fringes. Since I need both a minimum and a maximum, do I also need to consider both: m(wavelength) and (m+1/2)(wavelength) as per the definition for an interference min and max?
Hope you all can provide a bit of insight, as all of this new information is a bit overwhelming when you're first introduced to it...
Thanks,
B