Why is the the first order useful?

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The discussion centers on the use of diffraction orders in Acoustic Optical Light Modulators (AOLM) and Digital Micromirror Devices (DMD). The zeroth order of diffraction is often discarded because it is not modulated, meaning it does not carry the desired signal information. The first order is preferred due to its higher power compared to higher orders, while the zeroth order remains unaltered by the modulation process. The conversation also touches on how the modulation of light occurs through changes in the refractive index caused by sound waves in AOLMs, which does not affect the zeroth order. Overall, the zeroth order's lack of modulation renders it less useful in applications requiring signal processing.
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I've been looking into diffraction for AOLM and stuff like that, and these produce diffraction. Binary Spatial Light Modulators like Digital Micromirror Devices also produce diffraction. This diffraction is then focused and filtered using a pinhole. But, and here is the question:

Why is always the first order of diffraction used and not the zeroth order?

The first order has more power than the 2nd, 3rd or other higher orders. That's something I get. But why is the zeroth order of diffraction not used? I've been seeing on several websites that the zeroth order is not 'modulated', but why isn't it? Isn't the zeroth order just as valid to use as the 1st? I have added an image of a 4f system and you can see it discards the zeroth order. Why?

EDIT: AOLM stands for Acoustic Optical Light Modulator (more commonly known as just AOM) and adds the frequency of soundwaves to light. For an example, if you want to add several MHz to light (of several THz) you can do so using an AOLM.
 

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Do you really expect us to know what AOLM means? You got to be kidding. Even without really knowing what you mean, it's clear that the zeroth order is no good because it is not modulated. That means the signal you're looking for won't show up in the zeroth order fringe.
 
I get the zeroth order is not modulated, but why is the zeroth order not modulated?

PS: I added an explanation of what an AOLM is to my question
 
Choisai said:
I get the zeroth order is not modulated, but why is the zeroth order not modulated?

PS: I added an explanation of what an AOLM is to my question

Ask yourself this question: what is the AOM doing to the lens? How does this change with frequency?
 
It uses sound wave to change the refractive index. This index-modulation creates relatively more opaque and less opaque area, which acts like a grating. The zeroth order is made up of light coming through this grating, but I guess that isn't the part that gets refracted by the change in index? And therefore the zeroth order is the unmodulated order?

If these assumptions of mine are correct, how do they extend to more general applications, such Digital Micromirror Devices that use pinhole filtering? There is no change in refractive index when you use a DMD, only tiny micromirrors (usually 10 micron in size).
 
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