Researchers Developing Single-Pixel Camera

Assassin bug writes "According to the BBC, researchers in the US are developing a single-pixel camera to capture high-quality images without the 'expense' of traditional digital photography. The idea behind such a device is that traditional digital photography is wasteful. Most of the information taken in by the camera is thrown away in the compression process. From the article: 'The digital micromirror device, as it is known, consists of a million or more tiny mirrors each the size of a bacterium. "From that mirror array, we then focus the light through a second lens on to one single photo-detector - a single pixel." As the light passes through the device, the millions of tiny mirrors are turned on and off at random in rapid succession. Complex mathematics then interprets the signals assembling a high resolution image from the thousands of sequential single-pixel snapshots. '"

Yes, it's a dupe.

[Anonymous Coward]

A Single Pixel Camera [slashdot.org]
Posted by CowboyNeal on 10-20-06 12:44 AM
from the high-tech-pointilism dept.

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Still patented too

[goombah99]

The coherent detection version of this was patented 11 years ago.
Apparatus and method for heterodyne-generated, two-dimensional detector array using a single detector [uspto.gov]

Re:Still patented too

[Rei]

At first, I thought this was going to be similar to the method of generating hires images from a small number of sensors utilized by jumping spiders [wikipedia.org]. Basically, they vibrate [pbs.org] their [spacedaily.com] retinas [abc.net.au], recording datapoints from the in-between locations to get in-between pixels.

Re:

[alshithead]

I knew I saw this a couple of days ago on BBC. I was going to post something to the effect of "a little late on the draw there aren't we", then, I saw this is dupe. I must have missed the first post.

Re:

[x2A]

Unfortunately they turned out not to be very accurate when photgraphing girls. Mirrors, as everyone knows, makes them look fat.

HDR!

[ACMENEWSLLC]

What is cool about this is that it could allow HDR(http://en.wikipedia.org/wiki/High_dynamic_rang e_imaging) in the camera itself.

While you eye can see many different luminosities of light, a camera has limited contrast. Since it is taking not a single picture, but millions of them in an instant - it could also adjust contrast dynamically.

That would be cool.

Pointalism...

[__aaclcg7560]

If the one-pixel camera behaves like a traditional digital camera, I will need to take 100 pixels to get 20 decent pixels that I can use.

Not just for cameras

[k4_pacific]

In related news, a major roofing manufacturer has announced the "single shingle" roof. It consists of a small plate that is quickly moved about above a building during a rainstorm to block each individual raindrop. This eliminates the "complexity" of asphalt shingles.

Re:Not just for cameras

[Chandon Seldon]

That would work... if shingles were really expensive and the mechanism to move the one shingle around at the necessary speed were comparatively cheap. Oh... and you knew that you never needed to block raindrops in two places at the same time.

There are tons of ideas that work great in computerized systems that sound *really stupid* when you think of doing something that seems similar but uses other materials / technology. I mean - consider the mechanism of an ink jet printer from the perspective of a portrait artist who works with pencils...

Re:

[blugu64]

"There are tons of ideas that work great in computerized systems that sound *really stupid* when you think of doing something that seems similar but uses other materials / technology. I mean - consider the mechanism of an ink jet printer from the perspective of a portrait artist who works with pencils..."

Wasn't there a painted around the turn of the century that did something similar though? I can't remember the name of the artist sadly.

Re:Not just for cameras

[AK Marc]

Is http://en.wikipedia.org/wiki/Pointillism [wikipedia.org] what you were thinking of? I love a good Seurat.

Re:

[profplump]

http://en.wikipedia.org/wiki/Pointillism [wikipedia.org]
http://en.wikipedia.org/wiki/Georges-Pierre_Seurat [wikipedia.org]

Re:

[Agripa]

Wasn't there a painted around the turn of the century that did something similar though? I can't remember the name of the artist sadly.

This may not be what you are thinking of but I remember a series of painting that mysteriously displayed photograph like perspective that later were determined to have been made using the equivalent of a pinhole camera. The artist traced the outline of the scene while inside the darkroom on the canvas which was illuminated with the pinhole image.

On second thought, you were

Re:

[treeves]

You're probably thinking of Seurat, a pointillist [wikipedia.org], who built up his painted images from lots of little dots he made with his brush. Of course, he wasn't scanning across the canvas with three or four colored brushes dotting as he went but using some less deterministic approach.

Re:

[phorest]

Wasn't there a painted around the turn of the century that did something similar though?

Georges Seurat is the painter I believe you are thinking of. His most famous painting (to my knowledge anyway) is A Sunday on La Grande Jatte--1884 [artic.edu] located at The Art Institute of Chicago. There is even a Wikipedia page [wikipedia.org] devoted to Seurat.

I'm sure being included in Ferris Buehler's Day Off helped to raise its profile. There is also a scale model in topiary here [topiarygarden.org] (very cool!)

Re:

[Black Art]

Sounds like a "Breakout" product to me.

Murphy's Law

[Anonymous Coward]

Bet it'd suck to have a bad pixel with that camera, huh? :-)

Finally!

[Anonymous Coward]

Now we can get pr0n at the level of quality in Duke Nukem! One fleshy-pink-colored pixel is enough to get most me off...

Re:

[voice_of_all_reason]

Dude... aliens in disguise. You could even see the green tentacles sticking out.

Comment removed

[account_deleted]

Comment removed based on user account deletion

Re:

[speculatrix]

no, a beowulf cluster of 1 bit processor core CPUs.

RAW format anyone?

[Anonymous Coward]

> Most of the information taken in by the camera is thrown away in the compression process.

Doesn't the RAW format take care of this?

Re:RAW format anyone?

[John Meacham]

The problem is not getting at that extra information, like you say, we can already do that with RAW. the problem is that a lot of resources (such as CCD area) go into capturing this extra information which is then simply discarded. By taking a random sampling of pixels, one gets exactly as much information is needed to construct the compressed version of the image without waste. plus, with only a single CCD, you can make it incredibly sensitive, to the point where it can count single photons. Heck, you could probably have some fun with wavelengths. different wavelengths get diffracted slightly differently, if you could take advantage of that to redirect photons of different wavelengths at the sensor. you could have a camera that takes _full spectrum_ pictures. not just at the single pretty but not very informative red green and blue lines. (tetrachromats rejoice!). Full spectrum sampling in a small package would be really cool, I mean, that is tricorder technology. This is very neat research.

Re:RAW format anyone?

[Pieroxy]

There is always a catch, however. Let's take an example of a 1MP camera, taking a picture at 1/100th of a second. Each CCD can acquire light for a full 1/100th of a second. But each one is small and as such, not very sensitive.

Let's say this new 1 pixel camera is set-up to take a picture of 1MP at 1/100th of a second. Each one of the 1M mirrors will reflect its light on the CCD for ... (1/100)/1000000 th of a second, because only one pixel (of the final image) can be recorded at a time. So yes, the new sensor will be more sensitive. And it better be ! 1 000 000 times to be correct (for 1MP pictures.)

Re:

[Goaway]

Incorrect. Even the summary implies that it lets a lot of different pixel shine on the sensor at any moment, and untangles it with maths afterwards. It still needs to be faster, but there's also just one, and it can be big.

Re:

[dangitman]

the problem is that a lot of resources (such as CCD area) go into capturing this extra information which is then simply discarded.

What do you mean discarded? I use every pixel of my digital SLR in RAW mode, and I often wish there were more pixels. A lot more. So, where am I discarding these pixels?

Re:

[Thuktun]

Heck, you could probably have some fun with wavelengths. different wavelengths get diffracted slightly differently, if you could take advantage of that to redirect photons of different wavelengths at the sensor. you could have a camera that takes _full spectrum_ pictures.

The limiting factor there would be finding a material that allowed you to reflect or diffract photons all the way from infrared light to x-rays. Since we're talking about a single-pixel sensor, constructing separate sensors for the various areas of the EM spectrum would probably be more feasible.

complex mathematics?

[superwiz]

Surely, you mean "complicated". Mathematics already has a use for the word "complex".

Re:complex mathematics?

[Jerf]

It's a little clue for those "in the know" that the described benefits are entirely imaginary.

Re:

[rherbert]

Perhaps they're implying that the mirrors move in Hilbert space, which would be quite an accomplishment.

Re:

[x2A]

Yes, but the word was not used within the mathmatical context.

Throwing away data?

[kerohazel]

Well, there's no reason a digital camera *has* to throw away any data at all. It's likely the case that all digital cameras do perform on-the-fly JPEG compression, but it's not a limitation of the hardware, so why bother reinventing the wheel if you really care about losing data that much? Just make a digital camera that saves pictures as some lossless format.

And at any rate, how are the single-pixel cameras throwing away any *less* data than their plain digicam counterparts? Doesn't it all just depend on t

Scanning back?

[MoxFulder]

I think this design is sort of like an ultra-fast scanning back [wikipedia.org]. A scanning back is a high-end type of digital camera sensor where the sensor has only a very small resolution, but it physically moves and takes a frame at each step. The many resulting frames are then interpolated together appropriately. This can produce EXTREMELY high-resolution images (we're talking 100s of megapixels) but it is sloooow (minutes or hours per exposure). Good for art reproductions and such.

As I understand it, this camera

Re:

[x2A]

Tiny pixels have a chance of being triggered by a single stray photon (or something), causing speckles on the image. You can figure out the anomalies by taking multiple readings from each pixel, and discarding any that are very different from the rest, but that can be slow. Or, you can discard based on pixels very different from their surrounding pixels, and replace with the average of surrounding pixels, and then you start to lose picture quality.

Using lenses, each mirror can capture light from a larger ar

Need help making sense of this...

[posterlogo]

FTA: Compressive Sensing is an emerging field based on the revelation that a small group of non-adaptive linear projections of a compressible signal contains enough information for reconstruction and processing. We have developed algorithms and hardware to support a new theory of Compressive Imaging. Our approach is based on a new digital image/video camera that directly acquires random projections of the signal without first collecting the pixels/voxels. Our camera architecture employs a digital micromirro

Re:

[0xABADC0DA]

It's more like linear algebra... you have a series of equations based on the random-ish mirror patterns, so for a simple 2x2 grid of pixels (mirrors):

1*x0y0 + 0*x1y0 + 1*x0y1 + 0*x1y1 = sample1
1*x0y0 + 1*x1y0 + 0*x0y1 + 1*x1y1 = sample2
0*x0y0 + 1*x1y0 + 0*x0y1 + 0*x1y1 = sample3 ...

Then you basically solve it for the pixels. So think interpolating the entire image at once as a single value.

Re:

[x2A]

"then you can in theory reconstruct your compressed signal from cN observations"

THE SPEED OF LIGHT TIMES N?!! That'll take forever!

"(with c some constant)"

Oh...

We'll See...Betamax anyone?

[MuChild]

1) Create a million bacteria-sized mirrors. 2) ???? 3) Profit!

Single pixel reflector telescope

[heroine]

Always thought the single pixel idea would be more practical in a reflector telescope. Such a telescope could have a much higher dynamic range than any other telescope due to the extra money available for the pixel. The telescope would use the Earth's rotation to scan one axis and servos to scan the other axis.

Re:

[Cecil]

That would require *extremely long* exposures. You can't really up the sensitivity of the detector no matter how much money you throw at it. Good CCDs are already at the level of being able to record single photons, and it still takes hours or even days for some exposures. So what's a several hour exposure multiplied by a million pixels? Ouch is what it is.

Re:

[Hijacked Public]

You can't really up the sensitivity of the detector, but you can change what you do with the signal it sends once you get it.

With current pixels densities (say about 16MP on a full frame 35mm sensor) the signal can be boosted to give the ISO equivalent of 3200 speed film before the noise becomes objectionable. Noise is a problem in part because signals from adjacent pixels affect one another, which is magnified when the signal is boosted to ISO 3200.

I would suppose that a single pixel would be less prone to

Hot or stuck pixel?

[jo7hs2]

Oh great, now I'll end up with a camera with a stuck or hot pixel and be totally screwed. Thanks, progress.

Re:

[mobby_6kl]

Well, you could always use the dark frame subtraction method to fix the problem.

Re:

[cfulmer]

Actually, I don't think you could. If you had a mirror that got stuck into the 'on' position (i.e. it's pointing at the single sensor), it would partially blind the sensor whenever any other mirror was also pointing at the sensor. If that one mirror happened to be seeing pink, the entire photo would have a pinkish hue. If it happened to be seeing white, the picture would be washed out. If it happened to be seeing pitch black, well, then you're in business.

it's called "Compressed Sensing"

[toby]

And this story hit the UK Guardian on 9 Nov 2006. [guardian.co.uk] (via CS maven my slice of pizza [blogspot.com].)

I used it for my holiday snaps

[Timesprout]

This is me skydiving
.

This is me swimming with dolphins
.

This is me at the grand canyon
.

Re:I used it for my holiday snaps

[Anonymous Coward]

This is me having sex with my wife (NSFW)

.

Re:I used it for my holiday snaps

[MindStalker]

Dude, you should link stuff like that and no post directly.. I really didn't want to see your ugly whale of a wife..

mod parent down!

[Achoi77]

freakin goatse trolls!

Re:

[Asgerix]

That's the good thing about dupe posts; you get to improve on your jokes!

http://science.slashdot.org/comments.pl?sid=201687 &cid=16513113 [slashdot.org]

Single-pixel DLP-type camera is cool because...

[inviolet]

...with only a single CCD pixel, they can spend all their resources making it exquisitely sensitive, so as to outperform normal array CCDs.

Of course, they'd have to do that anyway, because to get a decent shutter speed they're already going to have to 'scan' the viewed area extremely quickly. It's the old tradeoff of serial versus parallel processing.

Re:

[radarsat1]

I'm gonna sit and wait until they perfect this, and just before it gets popular (because its so cheap) I'm going to patent the 2 pixel camera with twice the resolution for only a tiny higher cost, and beat them at their own game!

Mouahahahah...

Re:

[Jeremi]

I'm gonna sit and wait until they perfect this, and just before it gets popular (because its so cheap) I'm going to patent the 2 pixel camera with twice the resolution for only a tiny higher cost, and beat them at their own game!

You joke, but it might be a good idea... there's no need to stick to either the one-CCD-pixel-per-camera or the one-CCD-pixel-per-image-pixel extremes. Perhaps there is a happy medium somewhere, like having 256 scanning-CCD-pixels operating in parallel to build up a (simulated) 16-

Ah, more moving parts. THAT's helpful.

[ScentCone]

Is it just me, or does the concept seem inherently more complex and fragile than a multi-pixel sensor with light cast on it?

And how can this possibly deal with the equivalent of a range of shutter speeds in front of a standard sensor? Perhaps it's a matter of how many times the pixel is exposed to the same part of the lens' projection in repeated scans... but that just seems clunky, and that much harder/slower to re-assemble into a stored image.

And it doesn't stop the megapixel chest thumping - it just starts up megamirror arguments, instead.

Re:Ah, more moving parts. THAT's helpful.

[Jeff DeMaagd]

Micromirrors are actually very reliable and even exceed the lifetime of a typical LED now, of hundreds of thousands of hours of constant flexing. It turns out that nano-scale objects have different properties. A piece of metal on the nanoscale is likely to be a single crystal and that usually eliminates the fatigue issue. I think this has more uses in the sciences though.

Re:

[jandrese]

It still sounds to me like a camera with literally millions of moving parts though. Also, the sheer physics of getting the photons to the sensor (especially in low light conditions) when each pixel only has the most absolutely tiny slice of time to collect light seems rather difficult to surmount. In low light conditions it's easy to see where this could amount to only a handful of photons per pixel. It's hard to see how you wouldn't get lots of noise in low light conditions just due to the magnified eff

Re:

[pla]

And how can this possibly deal with the equivalent of a range of shutter speeds in front of a standard sensor?

Not to mention, you get the previously-not-an-issue joy of temporal aliasing.

And you thought the flicker of fluorescents annoyed you now? Wait until any exposure longer than 1/120th of a second includes both the "lit" and "unlit" version in one picture. Good luck figuring out the meaning of white and black levels on that monstrosity...



And it doesn't stop the megapixel chest thumping - it

Re:

[voice_of_all_reason]

Stating the researchers are talented is just as much an assumption as suggesting the GP is from the peanut gallery. Maybe they deserve turds.

Re:

[Goaway]

Just when you thought Slashdot couldn't get any more idiotically arrogant...

I have to say it

[JohnnyGTO]

oops, crash sevem million years bad luck !?!

Urgh!

[HerrEkberg]

Look how many MegaMirrors my new camera has!

Excuse me

[markov_chain]

Please don't move until I sequentially activate a few hundred thousand micromirrors!

'nuff said.

Dupe

[rumith]

From the mysterious past: http://science.slashdot.org/science/06/10/19/22552 39.shtml [slashdot.org].

Re:Dupe

[orson_of_fort_worth]

Shh. We can score some karma by copying the +5 posts from the original story.

Re:

[Aladrin]

"Comment Submitted. There will be a delay before the comment becomes part of the static page."

'nuff said.

Sigma-Delta Modulation

[sitturat]

It sounds very much like Sigma-Delta Modulation (http://en.wikipedia.org/wiki/Sigma-delta_modulati on [wikipedia.org]). Lots of samples in time, fewer bits.

Contradicts itself.

[Xoltri]

The article says that this new camera will have do do "Complex mathematics to interpret the signals" but at the same time will "do away with the need to process and compress each image". So which is it? I just don't see how this will save anything if you have 1 pixel doing something 5 million times or 5 million pixels doing something one time.

Re:

[dangitman]

The other benefit is that more money can be put into a higher quality CCD (such as one that senses in UV or IR).

Say what? Don't CCDs inherently respond to UV and IR? The problem is filtering out the IR and UV so it doesn't affect the visible spectrum and therefore your normal photos. This is why cameras have IR and UV filters over the sensor. To modify a standard camera to shoot IR for example, you simply remove the IR filter. And add an IR-pass filter if you want pure IR, rather than visible+IR - but that's not necessary.

pixels for mirrors?

[jackelfish]

So essentially, it seems that we go from an array of pixels on the photodetector in the camera, from which the data being collected is filtered and redundant information is deleted during compression into a jpeg. Now a new "less wasteful" method uses an array of tiny mirrors that must turn on and off and then focus the reflected light efficiently onto a single photodetector that then just filters the information using some complex maths? I am not quite sure how this is better, or is it just different?

best of both worlds

[cpearson]

Why could this idea be combined with the current technology. Millions of mirrors AND thousands if not millions of photo detectors would allow faster exposure times without as much waste as current CCD digital cameras.

Windows Vista Help Forum [vistahelpforum.com]

Re:

[jo7hs2]

Not everyone wants faster exposure times. Default faster exposure times would ruin many shots. Forget motion blur, water blur, etc... Everything would be a perfect freeze-frame. Of course, the consheepers would get razor sharp pictures of their sticky, chocolaty offspring.

If it were for these guys....

[d0n quix0te]

We'd still be using a pin hole camera... lenses --wasteful, shutters-just extra parts, zoom -- why would you need it...

-S

Compression

[gilesjuk]

Doh! so what if data is lost in compression? that's why you shoot in RAW format dumbass.

With a 4GB CF card and average RAW image size of about 20MB I don't see any need for JPEG if you have the time to work on the RAW files.

Re:

[Bandman]

I'm torn about this.

There are some shots that I'd like to get that just arn't worth the post processing that raw entails, and they take away from the "good" shots I'm interested in. That being said, I agree with you, RAW is the way to go for any serious photography that doesn't involve film.

Re:

[sahonen]

My camera lets you choose whether to shoot RAW or JPG. If you don't want to post process, shoot JPG, if you do, shoot RAW.

Forget about a solid state sensor for each pixel,

[sharkb8]

You can have a million little moving parts in your camera!

The microelectrical mechanical device fabrication techniques used to make the DLP scanning mirrors are taken from tech used to etch transistors. Instead of a circuit bring etched, a movable mirror os etched into slicon or other substrates. And you end up with a bunch of little tiny mirrors moving around on a portable device. Moving parts tend to wear out more rapidly than solid state parts, and are more easily broken. I'd be interested to see how durable this tech is. DLP doesn't have this issue because no one carried a DLP projector or TV around.

Seems like it would have one huge drawback

[Solandri]

Low light sensitivity. Digital cameras gain light sensitivity by acting as light buckets. Moreso for CMOS sensors than CCD, but the important thing is that all those sensor pixels are collecting light for their individual pixel simultaneously - in parallel. With a single pixel sensor, this light collection would have to happen in series to achieve the same light sensitivity. If your shutter speed in low light is 1/25 sec with a 5MP traditional digital camera, in order for a single-pixel camera to take the same picture it would need an exposure time of (1/25 sec/pixel)*(5M pixels)*(10% assumed algorithmic efficiency) = 20,000 sec = 5 hours 33 min 20 sec.

Of course since you're doing all this with mirrors, you could set up a megapixel array and have different mirrors shine at different pixels simultaneously (just like a DLP). But that seems to defeat the purpose of the whole rig.

Excellent tool for espionage...

[maillemaker]

I have sometimes thought of nano-sized cameras like this that, instead of having a million mirrors to allow a single pixel to take a full picture, instead, only took a pixel's worth of a picture. But each device is like a grain of sand. You could sprinkle the devices where someone is known to be passing through, or sprinkle them on the person, and thousands of these one-pixel devices, working in concert, could generate images.

It would be like "dusting" someone with micro-bugs.

Re:

[ShooterNeo]

Right, and in the future, where manufacturing even ordinary objects atom by atom is practical, the future society would have ubiquitous surveillance. EVERY object everywhere would generate ultrahigh res images of everything around it, and nano-scale processors embedded in the objects would analyze the images. Crime would be impossible : even committing a crime would be impossible, as an attempt to commit a major crime would automatically cause an intervention by the AIs watching over everything.

Random?

[Have Blue]

Why don't they just scan over every mirror on the chip in a specific order? Then there would be less complicated mathematics required, right?

Millions of Mirrors * 7 years bad luck = ..uh oh

[JustASlashDotGuy]

'The digital micromirror device, as it is known, consists of a million or more tiny mirrors



Drop this device just one time and you've got bad luck for the rest of your life... or next
million lives if you believe in reincarnation.
I urge all Eisoptrophobia'ist to avoid this at all cost!

Space/Time tradeoff

[phliar]

If you replace a million sensors with one sensor, for the same sort of exposure you'll need a million times the time. (Or, since the claim for the device is that you don't need to sample everything since you're compressing with JPEG, let's say half a million times.)

But we want the entire frame to be captured in "the same instant" (or you'll see strange artifacts from moving objects).

Let's say we want an exposure of about 1/100s. So, can these micro-mirrors switch at a 5x10^7/s rate (20 nanoseconds)? Sin

Re:

[Negadecimal]

If you replace a million sensors with one sensor, for the same sort of exposure you'll need a million times the time.

Bingo. And to "compensate", you'd have to tweak up the CCD sensitivity to the point of unacceptable noise. I'd also suspect that the power requirements for mechanically moving mirrors would be prohibitive.

Grainy pics, blurry action shots, and a five minute battery life? heh..

The basis

[Jerf]

Here's some of the basic math behind the idea:

When you lossfully compress an image, you are literally throwing away data. If you compress a 1MB image down to 100 KB, which with JPG is still very good quality, you are mapping many, many, many slightly different but ultimately very similar source images all onto the same compressed image.

Consumer cameras "waste" time starting from a full lossless image, and compressing it with JPG; the waste comes from collecting all of this data that has no bearing on the final result. (Anything that stores the .RAW of the image isn't doing this compression, it's storing the entire data set.)

The idea of this system is that by mixing the pixels together in a certain way, we can collect less information in the first place. For what would be a 1MB picture in a standard camera, you'd start off by only collecting 100KB of information, and then computing the image from your sequential numbers.

Two problems leap to mind:

• I find it very, very hard to believe that "random" is the optimal approach. I would have thought there would be something much better than that for the bases, but I could be wrong. (There almost certainly is something better than "random" but it may not be better enough to justify the computational expense.)
• JPG bases were carefully designed to match the human visual perception system and make it difficult for us to perceive the compression artifacts. The compression bases in this situation will have to be optimized for information gathering, which won't be the same as the human eye, which will result in somewhat inferior pictures, bit for bit. If you know what you're looking for, you can see it in their sample pictures; it's going to take a lot more bits to make that mosaic effect "go away" that it will to make JPG artifacts "go away".

A clever PhD may be able to solve both problems in one swipe, by using a clever mirror progression that happens to map better to the JPG standard. (You can't get it perfect though because you can't predict in advance how many bits go to one JPG block, that's computed dynamically.)

It works, and it's a clever algorithm, but I would definitely still question its practical usefulness over a conventional imaging system. I think the current trend of compression is temporary; the megapixel race should start to slow down (who needs 100megapixel pictures of their baby?) and then as cameras and storage continue to advance, we'll start getting uncompressed or losslessly compressed images instead. I could see this technology winning the race to be the first to produce a single camera that matches the image capturing power of the human eye, though; by manipulating the incoming light you may better be able to manage widely varying light levels.

(Finally, bear in mind before posting criticisms of how impossible this all is that they appear to have actually built a device that does this, which trumps skepticism.)

cheaper?

[burnin1965]

Are micro-mirror arrays truely cheaper to produce than a CCD or CMOS photo sensitive array?

Single pixel?

[dal20402]

The QuickTake is back.

Exposure?

[dangitman]

Modern cameras have sophisticated algorithms to determine automatic exposure based on the composition of light and dark within the frame. To get the proper exposure with this system, it seems to mean you'd have to pre-scan the scene to get the exposure value. Or go back to old-school external light sensors rather than TTL (Through The Lens, not Transistor-Transistor Logic) metering.

A tremendous breakthrough!

[meanfriend]

Single pixel images will revolutionize the efficiency of porn sharing.

Are you into hentai? Here you go! .....................

Barely legal teens? Coming right up .......................

Even goatse freaks dont need to be left out:
.

Though I'll probably get modded down for that last one :(

One Dead Pixel!

[BenJeremy]

Just my luck, and the warranty says I can't return it unless I find at least 4 dead pixels!!!

Re:

[Marxist Hacker 42]

Yep- and just as crappy as the original DLPs. DLPs work because they have *very* high processing rates- unless the subject of the picture you're taking is perfectly still, I don't see this as being a big advance in digital photography.

Re:

[Marxist Hacker 42]

I'd like to know how having a million "tiny mirrors" is less wasteful than having a million pixels.

THAT depends on the manufacturing process- it's entirely possible that the material needed to create the mirrors is cheaper than the material needed to make a pixel sensor. However, having said that- you know how bad digital cameras are now at storing the picture once you snap the button, just based on flash memory time to store? Think a million times worse, as each pixel is scanned individually, then reas

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[x2A]

"Think a million times worse, as each pixel is scanned individually, then reassembled to store on the flash card"

Well tha's not actually true, as the photograph isn't put together until each of the mirrors has had a turn at the sensor at least once, which means the camera must have enough fast memory to store the data from the readings and process it.

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[Marxist Hacker 42]

It doesn't matter how fast the memory is- you're still only recording one pixel per whatever clock cycle the camera uses. Thus giving plenty of time for the subject you're looking at to move.

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[x2A]

How many bits at a time do you think a harddrive head can read?

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[Marxist Hacker 42]

How many bits at a time do you think a harddrive head can read?

One per head, buffered. But unlike bits on a hard drive, subjects in real life MOVE. Just because you read a pixel on one side of the picture one nanosecond, doesn't mean that the next nanosecond that pixel will be the same. By using the mirrors instead of a massively parallel system, you're moving the serial from the connection to the hard drive or long-term memory storage, to actually taking the photo. Which will, at best, cause some pre

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[x2A]

"Look at the website referenced in the story- you'll see what I mean in their sample photos of even still items"

*pmsl* what way exactly do you think that photos of a STILL SCENE in any way reflect (hehe, reflect) image loss that WOULD be caused by taking photos of a moving scene?!!

Anyway, this isn't a simple case of turn-by-turn turning on each mirror then off again, at any one sample time multiple mirrors will be reflecting to the sensor, and for each photograph taken, each mirror will have been read from

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[speculatrix]

basically yes. the example images are crap, they're a long way before they can produce something that'll compete with a 50$ digicam!

I would like to refer /. crowd to the fact that telescopes use mirrors and not lenses for good reasons, so perhaps a DLP mirror array with one sensor could make sense under certain circumstances... this might be an advantage is IF the image sensor had very peculiar characteristics that were very hard to reproduce in a large 2D array like a CCD or MOS sensor. Off the top of m

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[AmigaAvenger]

you do realize most telescopes have both mirrors and lenses right? a pure newtonian onto a camera/ccd is only mirrors, but every other design utilizes lenses.

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[speculatrix]

this is /. so I figured brevity to keep attention span was more important than a detailed technical explanation :-)

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[x2A]

"I would like to refer /. crowd to the fact that telescopes use mirrors and not lenses for good reasons"

Well, they do often (or always?) still use lenses, but if you stick one mirror in there, you could half the length of the telescope (assuming you're bouncing the light the complete length of the telescope) or the thickness of the lens, and the effects are obviously greater if you curve the mirror too. Not such an issue when you have plenty of light.