Polymer 'Muscle' Changes How we Look at Color

New Scientist is reporting that in the not-so-distant future computer monitors, and televisions may utilize a color changing polymer that responds to a current instead of existing techniques. From the article: "Aschwanden and colleagues built arrays of 10 pixels, each 80 micrometers across. The pixels consist of a piece of polymer covered with ridges tipped with gold. When white light is shone at the polymer from one side it reflects out of the screen and is also split into different wavelengths by this 'diffraction grating'. However, a slit above the polymer ensures that only one wavelength of light escapes, giving the pixel its color. The pieces of polymer also contract in response to current, like simple muscles. As they do so, the fan of light-waves is moved, changing the color that is fed through the slits above and out of the screen. Cutting the current causes the muscle to return to its original state."

Application in fiber optics?

[chriss]

I like the idea of reducing our current RGB model to a "true pixel" technology, because it will make displays smaller, sharper and more. But as far as I understand our vision system is itself based on a sort of RGB sensor and the human eye is not really capable of seeing e.g. orange, which is why the whole RGB (and CMY) display technology works in the first place. There are some high range displays (at least in research facilities) giving you a larger dynamic per color than the 256 scales of traditional 24 bit images, so the lack of "true colors" mentioned in the article might be solved by conventional technology.

But what about the use for data transfer over fiber? One of the nice things about fiber is that you can send several "colors" in parallel which will not disturb each other, something impossible with copper. Up till now they use laser diodes with a fixed wavelength, so the number of diodes determines how many parallel signals you can send.

Now there is a technology that can create any wavelength. Combined with matching optics, could one not use one of those polymer displays to create multiple wavelength signals and send them through one fiber, in theory allowing an indefinite number of signals? Still limited by the number of pixels on the display and the accuracy of the sensors on the other side, but much easier than to arrange several thousand laser diodes.

[Just speculating, no real clue about optics.]

Re:Application in fiber optics?

[QuantumFTL]

But what about the use for data transfer over fiber? One of the nice things about fiber is that you can send several "colors" in parallel which will not disturb each other, something impossible with copper. Up till now they use laser diodes with a fixed wavelength, so the number of diodes determines how many parallel signals you can send. Now there is a technology that can create any wavelength.

We've had this for some time now. It's known as a tunable laser.

Potentially neat.

[CosmeticLobotamy]

For certain applications. It's my understanding that usually the synthetic muscle stuff isn't particularly speedy in changing shape. My first question is how many flips per second can you get? Are we aiming for TVs or variable paintings? My second question is about power requirements. 300 volts, sure, but are we talking amps or microamps?

Neat, as most science is, but possibly not terribly useful.

Requires lots of bandwidth for (uncompressed) data

[Zarhan]

So we have a "pixel" that can be truely any color. Does it mean "any" color, as in Hue, or can it truely be of anything (ie. full spectrum output; Image of fluorescent light would have spiky spectrum, etc.). If the former, instead of RGB we can simply transmit HSV (Hue-Saturation-Value(Brightness)), but if it's a continuous spectrum...

Instead of transmitting just RGB values from 0-255 (24 bits) per pixel, instead you have to somehow convey the entire spectrum. At what resolution do you get? Instead of three values (R, G and B) do you get 400 (one per nanometer, from 300 to 700 nm?) - or 4000? What kind of format do spectrograms use?

Anyway, consider transmitting data from a spectrogram - times some standard monitor resolution - for multiple frames per second. That's a lot of uncompressed data.

Digital x Analogic

[marcosdumay]

At the time you put it on a real product, it makes no difference (maybe outside the price) if you have an array of leds or a device capable of emiting any frequency. You receiver won't be able to read on a perfectly sharp spectrum, and light will scatter on the fiber, adding noise to the frequencies close to the ones you are using.

At nature, you never have infinite precision, so anything you do can be discretized.

Tetrachromats Rejoice!

[QuantumFTL]

The ability to generate any visible light frequency would not only extend the gamut to the full human range (unlike other schemes, like the 6-color Iridori system presented at SIGGRAPH 2004), but it would also allow tetrachromats to enjoy television and computers much better (this issue was discussed previously on slashdot).

Of course, as the article suggests, they will still have to use multiple emitters per pixel, as it can only generate colors on the edge of the CIE Color Space (warning, you can't see what colors they are, because your monitor cannot display anything outside the RGB Triangle). And of course tetrachromats are rare but have been found.

Neat, but...

[virtuald]

This is definitely an interesting technology, but I still think that display technology really has a long way to go before it can be used for general purpose things such as books and the like. The one thing that bugs myself about monitors/lcd's is that they always require a backlight or some active light source to function -- which IMHO really can bug the crap out of your eyes. What if they could invent a technology that didn't require a light source to be seen, but just reflected whatever existing light.. like a normal surface. Not only would this sort of thing definitely bring down the strain factor, but it would seem like you're reading a book or paper or something. Just a thought.

Re:Neat, but...

[mark-t]

It's called electronic paper and we have a ways to go with it yet. In particular, with regards to decent resolution with color technology. Last I heard they were only up to about 80dpi for color. Monochrome technology for e-paper is at 300dpi or better.

The refresh rate on this technology is also fairly slow... it's unacceptable for animation, but would be fine for relatively static images such as pages from a book. The display also only draws power while it is being changed, so it's very energy-friendly.

The displays are literally paper-thin, can be bent or rolled into a tube (but not folded) without being damaged, and are very lightweight. In time, it may be more economical for publishers to publish e-paper based books than paper books (any arbitrarily large number of pages in the book being condensed to a single viewable e-paper display that can display any one of them), but I don't see that happening anytime soon.