DLP Technology & Digital Mirror Device under Microscope and Image Test, CAUTION: Super Interesting technology device

Super awesome! Now I know what to look for next at eBay….by the way, if you would have played doom on this dmd, you would have beaten your record as I think the dmd is around one inch!

This was freaking awesome!
Thanks for the video.

Excellent. Best description I've seen.

I am also fascinated by DLP as a technology. DLP uses the * fast * mirror movement to reflect light in a direction or another (fully saturated color is 1 and no saturation color is 0). The 1 is fully reflected into the lens, the 0 is reflected away from the lens. How fast is that switching? It goes up to 9 kHz, that is 9000 times a second for each pixel (newer ones go up to 32 kHz). This is how they manage to get all the grayscale values for each color by synchronizing with the color wheel and setting the grayscale for each image 30 or 60 frames per second, that is about 90-180 frames per second to get the full spectrum of color. All the intermediate grayscale patterns are done by the rapid switching between the fully saturated state and no saturation state. This is easy because the chip is capable of up to 9000 Hz switching and being digital it can easily synchronize with the color wheel for full color rendering. DLP is capable of 1024 shades of gray for each color individually, that makes up 1,073,741,824 colors for RGB or even more for CYMK. The human brain is blending the rapidly switching images to get a fluid movement. I hope it clears your question at the end.

I must admit, I was looking forward to seeing the action of the DLP chip through a microscope.

The change in intensity is sorta not whats going on. This is a correction taking place to the color wheel. There are two different types of color wheel. One with 2 of each (blue,green,red) and another that has transition colors (ie a blend of two colors and a solid color. When there is a variation of a color outside the color band the transition color is used to give a better color tone. This requires more light. So the gradient changes when you go from a solid primary color to a in between color. Hope that makes sense.

You get a thumbs up for showing the into of Sakura Taisen on the DLP. 😉

They are a super cool addition to a collection! I got into DMDs a bit and managed some decent microscope shots of them running, though they where the pocket projector form factor which easily fit on the microscope stage. These have always fascinated me, the engineering is absolutely mind boggling. If you have a chance check out some of the MEMs micro mirrors, they are also really cool.

I never knew how DLP projectors worked. I always assumed it worked like a film projector as in the DLP chip had light shines through it. I always wonders how they could withstand so much heat. I never thought about the possibility of all those tiny mirrors physically moving. That's wild.

Pretty cool technology, and I love the look of those gray/gold ceramic chips.

The pixels are pulse width modulated, not sure of the frequency but these chips update pixels very very fast. It's amazing the speed, precision and sheer quantity of electromechanical parts on these devices. Look into the consumer "4k" projectors, they seem to be using 1080p chips but are doing some sort of pixel shifting, combined with up to 6+ updates (3 color wheel RGB x2) per 60Hz refresh you can start to see why the chip needs a big heatsink (aside from being blasted from the front with a few hundred watt lamp). Would be interesting to see a follow up investigation! Edit: Also it's electrostatic, so those pixels may not be dead, just stuck.

I have a friend that still has a working Hitachi Ultravison 57" widescreen DLP projection tv they had surprisingly good picture for the time. No idea what chips Hitachi ran only downfalls were there price and only 1080i interesting technology though never seen a close up of they chips before.

the brightness is controlled via pulse width modulation – switching the pixels on and of at a pretty high frequency. it should be possible to meassure that frequency with a photo diode, hooked up to an oscilloscope.
PS: i've recently come across the avegant glyph video goggles, which use miniature DLP projectors instead of the usual LCD or OLED displays. looking foward to trying those out. compared to 720p goggles sold for FPV, they're an absolute bargain.

It's impressive how MEMS completely flips what we understand of materials on it's head. The effects on the material like fatigue and such change completely to what applies in a macroscopic manner, hence they even work to begin with, the amount of deflection, how many per second and speed of the mirror deflections would be completely unfeasible in a macroscopic scale. Let alone the energy to keep flipping the mirrors fast enough for moving pictures with different shades of light.

Careful if you drop one of those, it's 2 million years of bad luck 😉

The reason why you can see different light levels from the Micromirrors is that your eye is integrating the perceived scene's light level over a given timescale, therefore if you keep flipping the mirrors at really high speeds, you can see an average light level which is proportional to the amount of time that the mirror is in the on position.

The chip itself doesn't really heat up that much but only a percentage of the light gets reflected, the rest is dumped as heat in the chip case. If you stick a piece of paper into the light in front of the chip it will be set on fire immediately. The light is extremely intense.

My daily driver (watcher) is still my Samsung series 8 LED DLP 62”. They’re LED for the light source unlike a lot that had a bulb that needed a bulb that needed replacing. Bought it new in around 2008 for ~$2000 cdn on sale. 1920*1080.

About 4-5 years after lots of use it started to get white dots (stuck mirrors) and black dots (dead mirrors). When it got to be too much I tore the whole set apart and ordered a new dlp module (about $250). There was a common failure on these where they didn’t put enough heat sink compound on the module. Added some good compound under the new module, and it’s been working perfectly since then.

I was hoping, that you show the working chip under the microscope somehow.

DMD doesn't grey scale. It dithers or pwm's

my favorite video to date

Very cool! Thanks! (DLP technology is really se yellow from se egg! ;-))