Improving Digital Photography

Milican writes "'It's easy to have a complicated idea," Carver Mead used to tell his students at Caltech. "It's very, very hard to have a simple idea...And now one of Mead's simplest ideas--a digital camera should see color the way the human eye does--is poised to change everything about photography. Its first embodiment is a sensor - called the X3 - that produces images as good as or better than what can be achieved with film.'" We had a previous story about Foveon last February.

Foveon won the PopSci Best of What's New for 2002

[Drakonian]

in Photography. Check out the article here.

This is hardly news...

[MarcoAtWork]

for an excellent (as usual) review of a camera based on this sensor check dpreview

http://www.dpreview.com/reviews/sigmasd9/

It's like the eye because...

[SuperKendall]

It sees a real "color" instead of on red/green/blue (dispersed in fine pixels of course). It may not be able to see red quite as well as other colors, but it only means that the sensitivity at the red level is the limitation you have for the picture as whole.

What you don't get is Moire patterns - at all!! That is what you probably hate when you say you hate "pixel noise" because it's totally obvious (due to the color changes), very distracting, and annoying to clean up after.

Re:It's like the eye because...

[tjwhaynes]

It sees a real "color" instead of on red/green/blue (dispersed in fine pixels of course). It may not be able to see red quite as well as other colors, but it only means that the sensitivity at the red level is the limitation you have for the picture as whole.

I don't think I agree - it still looks like a standard red/green/blue pickup (and that is exactly like the human eye - we don't have different cones for, say, lime green and grass green). There is possible mileage in having more layers picking up wavebands spanning a smaller range of wavelengths (and there are humans with 4 types of cone rather than 3 - tetrachromatic vision) but it's not going to matter too much for our normal vision. Useful for simple spectroscopy (colour profiles etc.) though.

What you don't get is Moire patterns - at all!! That is what you probably hate when you say you hate "pixel noise" because it's totally obvious (due to the color changes), very distracting, and annoying to clean up after

It's pixelated still so you will still get Moire patterns as soon as the smallest details are finer than the resolving power of the X3 bins (think Nyquists theorem). However, the bizarre colours you get from a fine-grained black and white grid shouldn't be present to the same extent as all the measurements of colour intensity are done at the same point in the X3 layer, as opposed to the different spatial positions of the red green and blue bins in a colour CCD.

Cheers,

Toby Haynes

Re:It's like the eye because...

[SuperKendall]

Sorry for my simplified use of the term "real color". What I was meaning by that is that you do not have to interpolate from colors received at sepereate locations. True the eye has seperate cones, but the end result (what we see) is color with no color moire (unless you trick the brain in some specific situations) and sharpness simialr to what you get from the X3 sensor.

Hate to break it to you, buddy, but moire patterns have nothing to do with digital cameras. They are easy enough to see with a human eye, anyway. You can get a moire pattern on a Foveon just as easily as on a regular sensor.

If you're talking about color moire, you are just wrong. read the DP review and look at the resolution tests. The X3 has no color moire at all. That is not to say it does not experience noise (it does). Just not color moire artifacts.

Show me an image from a Foveon that has Moire if you are so certain. Remember that JPEG compression causes artifacts too...

Umm... get a clue. Pixel noise has nothing to do with moire. It's NOISE -- more or less random fluctuation is the measurements of light that each sensor spot does. The amount of noise depends on a bunch of factors, such as temperature and the size of pixels on the sensor. That's why astrophotographers cool their CCDs in liquid nitrogen, and that's why professional digital cameras like Canon D1s, D60 and such have hugely lower noise than (relatively) cheapo consumer digicams.

As C3PO would say, "How Rude!". Yes I understand the difference between noise and moire. But when I see digital pictures that look like they have issues, usually the most noticable aspect (to me) is moire and not so much the noise (which mimics film grain to some extent so our brain does not latch onto it as looking so artificial, being trained by looking at years of film images).

That is why I was saying that if he hated noise, it might really have been color moire he was seeing and hating, not the actual noise from the CCD. Thus I was not saying moire was noise, I was saying that might be what he meant by noise.

Re:Pixel Noise

[tjwhaynes]

How is this at all like the way the human eye sees?

This foveon system is like the human eye inasmuchas the light photons penetrate multiple layers and register at more than one levels in the same spot. For example, take a look at this cross section of the human retina.

Current CCDs only collect one waveband of light at one area. To simulate colour, they collect three different wavebands in adjacent areas on the surface of the CCD. Hence the funky moire patterns you that you see in tightly patterned cloth on the sample piccies on the site.

I hate pixel noise in my digital pictures. I have heard that since red color has to be detected at the deepest part of the silicon there is an abudance of noise in the reds.

If the upper layers are completely transparent in the red, then your concerns don't apply. As long as the actual transparency of the upper layers is reasonable, then there is little cause to worry - traditionally CCDs are far more sensitive to the red end of the spectrum than the blue so even modest photon loss at the red end is unlikely to seriously degrade the pictures.

The other nice thing about this technology is that the spatial size of the light bins is approximately three times larger than that for the equivalent physical sized CCD - that means better signal-to-noise ratios for this new technology.

Anyway, the presentations look compelling. I await cameras with reasonable numbers of megapixels (say 4Mpixels +) and reviews...

Cheers,

Toby Haynes

Re:Uh-oh, here come the digital bashers.

[aussersterne]

Film still rules for taking pictures in low-light. Digital cameras just can't handle low-light situations, by their very nature.

Plus, the speed of film is better. Digital cameras aren't very good for action photography.

So, uh, yeah. Digital is great for posed shots in good lighting. So I guess it is the best. Whatever.

Remember, I said "please be sure you have used the gear".

The ISO 1600 and 3200 shots from the pro digitals are easily less grainy and have better dynamic range than their film counterparts. Try it. And my EOS-1D can do 1/16,000 shutter speed with zero lag. Is that fast enough for you?

Yet another person who is bashing without trying.

Re:Pixel Noise

[mohaine]

Current color CCDs only measure one of the primary colors at each pixel. Once a picture is taken, the missing colors are 'guessed' by looking at the surrounding pixels that did capture that color. This process is really slow because each pixel is missing 2 colors.

The X3 actaully measures RGB at each pixel, giving much better quality, at a higher speed.

Nyquist free...

[SuperKendall]

t's pixelated still so you will still get Moire patterns as soon as the smallest details are finer than the resolving power of the X3 bins (think Nyquists theorem). However, the bizarre colours you get from a fine-grained black and white grid shouldn't be present to the same extent as all the measurements of colour intensity are done at the same point in the X3 layer, as opposed to the different spatial positions of the red green and blue bins in a colour CCD.

The bizzare colors (what I really hate about digital photos) are not just reduced - they are gone. If you read the review at DPReview.com you'll find that it has resolution right up to Nyquist is noise free and you get some detail beyond. Here's the relevant section (near the very end of the review, where they test against some resolution charts):

The SD9 is capable of delivering all nine individual lines of the horizontal or vertical resolution bars up to its maximum absolute resolution (sensor vertical pixel count) and slightly beyond. Note also that because the X3 sensor doesn't need a color filter array it doesn't suffer from color moiré.. Absolute resolution is just less than the Canon EOS-D60, Nikon D100 and Fujifilm S2 Pro (at 6 mp).

However, because the X3 sensor doesn't use a low pass (anti-alias) filter it is able to resolve detail all the way up to Nyquist. Beyond Nyquist the system will alias without any objectionable color moiré. Where a Bayer sensor camera would turn detail beyond Nyquist (such as distant grass texture) into a single plane of blurred color the SD9 will continue to reproduce some individual pixel detail (without color moiré).

The future of digital image sensors

[Traa]

As much as Foveon's well hyped and widely advertised (*cough*thanksslashdot*cough*) idea seems to make sense on the surface, their solution is far from perfect.

To sense an RGB (Red, Green, Blue) pixel one can use a veriety of methods. At the center of this technology lies the ability to turn a stream of photons into an electric current. This photodetector is colorblind, it is only capable of measuring the _amount_ of light, not it's color. To recognize color the estheblished method used to be to put several photodetectors near each other and put color filters in front of them. The most widely used color filter array is known as the Bayer pattern and consists of 2 green photodetectors (diagonal from each other) a blue and a red detector in a 2x2 grid. These 2x2 blocks are then repeated over and over to create the full image sensor.
Specialized software or hardware needs to take these individual Red, Green or Blue pixels and recreate a single RGB pixel, this technique is known as demosaicing. The major advantage of this method is the simplicity of the photodiode (photodetector). It allows for the creation of very dense image sensors that are now passing the 10MegaPixel barrier while keeping the cost down (start seeing 5MegaPix sensors for less then $100 before the end of this year).

Foveon's approach is to layer these color filters vertically.

The good:
- idealy you get R,G,B at each pixel.

The bad:
- very complex layered photodiode technology, this makes the pixels significantly bigger. Currently the pixels are bigger then a 2x2 bayer image pixel. The complexity also adds to the manifacturing cost, these chips will not be cheap for the forseable future.
- Color bleeding. For example: Photons in the green wavelenght do not nescecarily stop in the green layer, but might be picked up by the underlying red layer. This means that specialized hardware needs to apply a non-trivial color correction for each pixel layer.

Foveon's idea is a very interesting approach. Since they nicely pattented their idea shut, we will have to patiently wait for this single company to provide the world with this technology.

Side fact: The human eye see's colors using pigments that respond differently to different wavelengths. In the simplest model we can say that we see Red Green and Blue with spatially seperated pigments that resemble a bayer image sensor closer then the foveon's sensor.

Re:Whats the hold up?

[StarFace]

Primarily because it is still a bit buggy and bleeding edge. CCD is a proven technology, with a lot of time put in to its development. That is why Nikon has stuck with CCD chips. Canon has been using Bayer CMOS chips in some of their prosumer cameras, but the top of the line 1Ds still uses a CCD chip.

X3 still displays some odd behaviors under certain conditions, and until these problems are resolved, the "big guys" aren't going to want to put it into a high end camera -- especially when their customers have grown to expect a certain level of all-around quality and attention to detail from them.