Black and White Mirror / Narrow Band Mirror

In summary, the conversation discussed the possibility of creating a mirror that reflects only shades of gray, similar to a black and white photo. Several methods were suggested, including using a regular mirror, duct tape, and a dark cloth to create a black and white reflection, or using monochromatic light to achieve the desired effect. Other options included using a web camera and monitor, or constructing an array of photovoltaic cells and LEDs to create a black and white image. Finally, the conversation also mentioned the use of fluorescent materials to create a black and white reflection, but noted potential challenges such as low efficiency and the need for a hidden UV light source.
  • #1
bugguy
1
0
I am looking for a mirror (11" x 14") that reflects only shades of gray.
Ideally the reflection would be like a black and white photo (The subject's reflection would be "black and
white").

Is such a mirror available?
If not, can one be made?
If so, by whom?

Thank you for your assistance.
 
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  • #2
You will need a regular mirror, some duct tape, and a reasonably opaque cloth, like a dark-colored T-shirt.

Tape the T-shirt over the light in your room, so that only a little bit of light can get out. Let your eyes adjust to the dark, and look in the mirror.

Your reflection is now in black and white.

---------

Or would you like to do it without reducing the amount of light in the room?

Your reflection appears in full color because light of every color is bouncing off of your body, off the mirror, and then into your eyes. If you want a black and white reflection, you need to interrupt the process at any point. Here are some possibilities:

1. Illuminate your body with monochromatic light.

2. Ensure that only monochromatic light is reflected from your body.

3. Ensure that only monochromatic light is reflected off of the mirror.

4. Ensure that only monochromatic light enters your eyes.

5. Ensure that only monochromatic light is converted to an image which is transmitted to your brain.

My flippant answer above used (5): I suggested a way in which you could shut down your color-perceiving cone cells so that only your black-and-white rod cells worked. We all see in black-and-white, in low-light conditions.

To perform a variant on (2), paint yourself white and wear a black shirt. Then your reflection would, in fact, be black and white.

The problem with all of these methods is that 'monochromatic' means one color, and grey is not one of your choices. Light only comes in the colors of the rainbow, red through violet. (And beyond, but we can't see those wavelengths.) Illuminating yourself with red light, or putting a good red filter on the mirror (or on your glasses) would give you a monochromatic, value-only image--the kind that you could use Photoshop to convert to what you think of as a black-and-white image. But seeing in red-and-black isn't as cool as seeing in white-and-black, is it?

Your 'mirror' could be a web camera, hooked up to a flat panel monitor. Not cheap, but doable. If it had a dedicated processor, it could run so fast you wouldn't be able to tell the difference.

If you don't want to use a computer or a camera, here's my final attempt:

Construct an array of photovoltaic cells, as small as possible. (These are semiconductor devices which produce a voltage proportional to the amount of light incident on their surface.) Isolate each diode by placing it at the end of a reasonably long (0.5 cm) tube pointing straight forward (all of these tubes could be integrated into one grid or honey-comb-shaped divider.)

Now connect each photodiode to a white LED, so that the amount of light produced by each LED is proportional to the voltage on its respective cell, and thus to the intensity of the light coming from (being reflected from) the user's face. The image would look an awful lot like a computer image, especially if the resolution were poor. But if you could make small enough cells, and pack enough of them onto one surface, then you'd have a reasonably convincing effect.

However, photodiode efficiency is about 10 percent, and so is LED efficiency, so only (0.1)*(0.1) = 0.01 = one percent of the light of the light energy that hit the 'mirror' would actually get reflected back at you. So it would be a black and white picture, but mostly black.

P
 
  • #3
One more thought.

Flourescent materials absorb light of one wavelength (usually ultraviolet) and re-emit in another wavelength, often in the visible spectrum.

If you could produce three sheets of translucent material impregnated with the right amount of flourescent material in three different wavelengths (preferably red, green, and blue), and then stack them one on top of the other...

You'd still need the collimating grid I described before, because in flourescence the output light is scattered in all directions, not determined by the law of reflection as for a regular mirror. But in this case, the resolution would be much better than for the photocells; it could easily be made so small you'd never be able to see it. Occultation would be a problem; the edges of your image would be darker, and the mirror would only work if you stood directly in front of it.

Also, you'd have to be illuminated by pretty high levels of UV. It might work okay on a sunny day, but I suspect you'd need a hidden UV source somewhere near the mirror, perhaps built into the frame like in a cosmetics mirror.

P
 

1. What is a Black and White Mirror?

A Black and White Mirror, also known as a Narrow Band Mirror, is an optical device that reflects light in two distinct bands of wavelengths: one for black and one for white. This results in a mirror that has a sharp contrast between black and white, with very little reflection in any other colors.

2. How does a Black and White Mirror work?

A Black and White Mirror works by using a thin layer of metal or dielectric material on a glass surface. This layer is designed to reflect specific wavelengths of light, allowing only black and white light to pass through. The wavelengths that are reflected depend on the type of material used and the thickness of the layer.

3. What are the applications of a Black and White Mirror?

Black and White Mirrors have a variety of applications in science and technology. They are commonly used in optical instruments such as microscopes and telescopes to improve image contrast. They are also used in laser technology, optical filters, and in the production of dichroic filters for photography.

4. How is a Black and White Mirror different from a regular mirror?

A regular mirror reflects all wavelengths of light, resulting in an image that appears in its original color. However, a Black and White Mirror reflects only specific wavelengths, resulting in an image that appears in black and white. Additionally, regular mirrors have a continuous spectrum of reflection, while Black and White Mirrors have distinct bands of reflection.

5. Are there any disadvantages to using a Black and White Mirror?

One potential disadvantage of using a Black and White Mirror is that it may not reflect all wavelengths of light, resulting in a loss of color information. Additionally, the production of dichroic filters can be expensive and time-consuming. However, for specific applications where contrast is crucial, a Black and White Mirror can be a highly effective tool.

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