I wonder if this has implications for custom home chips/prototyping. I'm sure a big issue is vibrations but something like this could remove the need for masks at least. (again, not my area so I am clobbering terminology I am sure). It may open up home fab capabilities.
I think abusing a write-off electron microscope to side step the need for masks is also an interesting idea, however, I believe acquiring wafers of sufficient quality and depositing layers to be etched could be the bigger challenge here.
This reminds me of the original patents that Magic Leap had, which involved pumping light through a single optical fiber that was wiggled by piezoelectrics into a spiral to project light (https://kguttag.com/2018/01/06/magic-leap-fiber-scanning-dis...).
> The chip projected a roughly 125-micrometer image of the Mona Lisa.
This may seem small (barely visible as a dot to the naked eye), but that's also the geometric mean of the Planck length and the diameter of the observable universe. So average size actually.
I wonder if this has implications for custom home chips/prototyping. I'm sure a big issue is vibrations but something like this could remove the need for masks at least. (again, not my area so I am clobbering terminology I am sure). It may open up home fab capabilities.
I think abusing a write-off electron microscope to side step the need for masks is also an interesting idea, however, I believe acquiring wafers of sufficient quality and depositing layers to be etched could be the bigger challenge here.
In general, hobby photo-lithography projects already use DMD/DLP projectors, and some inexpensive optics.
Huygens Optics:
https://www.youtube.com/watch?v=_w0Z2Y5vaAQ
Sam Zeloof:
https://www.youtube.com/watch?v=Nxz_ENnmgtI
In general, getting vanity silicon made is usually much less expensive than trying to bootstrap a fab line. =3
This reminds me of the original patents that Magic Leap had, which involved pumping light through a single optical fiber that was wiggled by piezoelectrics into a spiral to project light (https://kguttag.com/2018/01/06/magic-leap-fiber-scanning-dis...).
> The chip projected a roughly 125-micrometer image of the Mona Lisa.
This may seem small (barely visible as a dot to the naked eye), but that's also the geometric mean of the Planck length and the diameter of the observable universe. So average size actually.
What is this, a movie theater for ants?
It has to be at least 3 times bigger than this!
We can finally say yes to this question
or AR glasses?
How do you even fit a video projector onto something that small, the physics feel like they shouldn't cooperate.
This might be relevant for Augmented Reality headgear.
This is actually getting close enough to manipulate the _phase_ of light! And doing that would allow creating true holograms.
Or alternative true augmented reality glasses that are not limited to one focal plane.
Electro-optic modulators already exist — still no StarTrek. :(
Oh wait. It does have the correct title. My fruit flies are cheering.
[dead]
Cool. Now I can show videos to my fruit flies! /s
Srsly title should be "MEMS Array Chip the Size of a Grain of Sand Can Project Video"
not
"MEMS Array Chip Can Project Video the Size of a Grain of Sand"
It is actually about a 0.125mm projection, not the size of the chip. But more about steering lasers, which is really what they wanted to do.
This is revolutionary. No other way to put it.
It certainly looks like something that will find novel applications.