What happens when the source of light rays is a mirror?

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When light rays hit a camera's film, they converge from a single source, but each ray has a different optical path length, preventing interference effects. This means that even though rays may originate from the same point, they do not arrive simultaneously at the film, eliminating the possibility of interference patterns. When light reflects off a mirror, it consists of various frequencies, yet they still focus on a single point on the film. Despite this, the resulting photograph captures the color of the dominant ray rather than a mix of colors. The phenomenon highlights the complexities of light behavior in photography, where superposition of frequencies occurs without visible interference.
Brian99
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As far as I understand, the film inside a photo camera is positioned in such a way that every light ray that hits some spot X on the film comes from a single source on the object being photographed. Here's what I mean:

http://static.howstuffworks.com/gif/camera-diagram3.gif

The various light rays from the top of the pencil, no matter where or at what angle they hit the lens, will be focused to one point on the film.

If so, then I have two questions:

1. What about interference effects between the rays of light? Since they all hit the same point on the film, and come from the same source, it seems they will be coherent and should produce interferene at that point.
Yet we don't see that when taking photographs.

2. What about when the source of the rays is not an object (pencil, etc.) but a mirror? In that case, even if the rays come from the same point on the mirror, they are still of different colors (frequencies) since they are reflections of light rays entering the mirror. And yet, all these various frequencies from the same point in the mirror will hit one single spot on the film. Shouldn't this produce a mix of colors on the resulting photograph, instead of a picture of reflection that we expect?

Thanks - Brian
 
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1. Each ray has a different optical path length, so they will not arive at the lens or image at the same time. Thus there will not be any interference.

2. Everything we see is a superpostion of all frequencys present. This should not be remarkable.
 
Integral said:
1. Each ray has a different optical path length, so they will not arive at the lens or image at the same time. Thus there will not be any interference.

The rays that will arrive at the image at the same time will be coherent (since they are coming from the same source), thus there should be interference.

2. Everything we see is a superpostion of all frequencys present. This should not be remarkable.

Re-read my post above ...The following image shows the situation I have in mind: http://i2.tinypic.com/wsql2r.jpg

The green and blue rays are reflected off a mirror, at the same point, and then enter the lens and are focused onto a single point A [this will happen for every ray coming from the same point on the mirror]. As a result, any photodector/film/etc. on point A should detect a mix of all colors [from rays coming from all angles], yet in reality we only see one color from one ray.
 
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