Image Quality Analysis Fall 2003: A Glance Through the Looking Glass
by Derek Wilson on December 10, 2003 11:14 PM EST- Posted in
- GPUs
Texture Mapping and Filtering
In the beginning was the wire frame, and it was good. But texture mapping changed completely the face of computer generated 3D graphics. Everything from coloring, to lighting and shadows, to bumping and displacement can be done with texture mapping. For this discussion, we will be talking about mipmapping, bilinear, trilinear, and anisotropic filtering.To set the stage, our 3D scene has an object and a texture map (an image to be applied to the object). When we stare “through the looking glass,” we see that each screen pixel maps to a particular area of our object. Likewise, each area on the object maps to an area in the texture map. Unfortunately, a texture map has a fixed number of data points (pixels in the image), while the surface of the object is continuous. This means that it is possible for an area on the object to map to a position that lies between pixels in the texture image. In order to fill in the gaps, developers need to choose a method to interpolate existing data. The first method developers used to solve this problem was simply to make the color of an area equal to that of the nearest pixel in the texture map.
The image quality resulting from using the nearest texel (a pixel in a texture map) is something commonly referred to as pixelization (large blocks of color visible when objects with low resolution textures fill the screen). Anyone who's played early first-person shooters (like Doom, Duke3D, etc.) will know this from how the screen looks when pressed up against a wall.
To solve this, rather than using the nearest texel in the texture map, we can do linear interpolation. We take the 4 surrounding texels, and interpolate between the two pairs of pixels in one direction. With the two resulting points, we then do another linear interpolation to get something closer to what the color should be. This is called bilinear filtering.
The light blue color is interpolated linearly from the other two. |
Another problem with what we have already talked about is that when high resolution textures are used on a surface that is far away, one screen pixel can be mapped to an area in the texture map, while the neighboring screen pixels are mapped to entirely different areas of the texture. Essentially, the size of the screen pixel is much greater than that of the texel. The visual result of this is a shimmering or sparkling in distant textures.
We can fix this by making multiple versions of texture maps with different resolutions. These multiple resolution texture maps are mipmaps (as this is a description of mipmapping). A Level of Detail (LOD) calculation based on the distance of the area on the object that we are texturing to the viewer is used to choose a mipmap level with texels close to the size of (but not smaller than) screen pixels.
One of the things that is completely different between ATI and NVIDIA is the way LOD is calculated for mipmapped textures. NVIDIA uses the Euclidean distance (sqrt(x2, y2, x2)) in their calculations, while ATI uses a weighted Manhattan distance calculation (.28*x+.53*y+.19*z). This causes the way textures look to vary a great deal between GPUs when looking at anything but very near or very far surface.
Of course, we still have problems that we need to solve. When the LOD calculation dictates a change in the mipmap being used on a surface, we can see a discontinuity in the texturing of that surface. To combat this, trilinear filtering was devised. First, we do filtering on the two surrounding mipmap levels, then interpolate between the resulting values.
This diagram shows one way to do trilinear filtering. |
The result is a smooth transition between mipmap levels. Of course, there are plenty of different algorithms for doing all this interpolation, and there is not a GPU on the market that does full trilinear filtering all the time. This operation is very expensive to do for every pixel on the screen. There are plenty of optimizations to make trilinear faster, such as only doing bilinear filtering where banding isn't an issue. This is acceptable as long as there is no perceptible loss in visual quality.
But the madness doesn't stop there. As it happens, trilinear filtering is isotropic. What this means to us is that trilinear filtering produces blurry images when not viewed straight on. The reason this happens is that the pixels in the mipmap levels are laid out in a square grid. Anisotropic filtering allows us to change the shape of the region we sample and interpolate between each mipmap based on the viewing angle. (Think of this as needing to be done for the same reason tilting a square object makes the far edge look narrower than the near edge.) The way this is done is also up to the implementation, thus adding another level of complexity in determining the color of one pixel due to one texture on one surface.
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nourdmrolNMT1 - Thursday, December 11, 2003 - link
i hate flame wars but, blackshrike....there is hardly any difference between the images. and nvidia used to be way behind in that area. so they have caught up, and are actually in some instances doing more work to get the image to look a little different, or maybe they render everything that should be there, while ati doesnt (halo 2)
MIKE
Icewind - Thursday, December 11, 2003 - link
I have no idea what your bitching about Blackshrike, the UT2k3 pics look exactly the same to me.Perhaps you should go work for for AT and run benchmarks how you want them done instead of whining like a damn 5 year old..sheesh.
Shinei - Thursday, December 11, 2003 - link
Maybe I'm going blind at only 17, but I couldn't tell a difference between nVidia's and ATI's AF, and I even had a hard time seeing the effects of the AA. I agree with AT's conclusion, it's very hard to tell which one is better, and it's especially hard to tell the difference when you're in the middle of a firefight; yes, it's nice to have 16xAF and 6xAA, but is it NECESSARY if it looks pretty at 3 frames per second? I'm thinking "No"; performance > quality, that's why quality is called a LUXURY and not a requirement.Now I imagine that since I didn't hop up and down and screech "omg nvidia is cheeting ATI owns nvidia" like a howler monkey on LSD, I'll be called an nVidia fanboy and/or told that A) I'm blind, B) my monitor sucks, C) I'm color blind, and D) my head is up my biased ass. Did I meet all the basic insults from ATI fanboys, or are there some creative souls out there who can top that comprehensive list? ;)
nastyemu25 - Thursday, December 11, 2003 - link
cheer up emo kidBlackShrike - Thursday, December 11, 2003 - link
For my first line I forget to say blurry textures on the nvidia card. Sry, I was frustrated at the article.BlackShrike - Thursday, December 11, 2003 - link
Argh, this article concluded suddenly and without concluding anything. Not to mention, I saw definite blurry textures in UT 2003, and TRAOD. Not to mention the use of D3D AF Tester seemed to imply a major problem with one or the other hardware but they didn't use it at different levels of AF. I mean I only use 4-8 AF, I'd like to see the difference.AND ANOTHER THING. OKAY THE TWO ARE ABOUT THE SAME IN AF BUT IN AA ATI USUALLY WINS. SO, IF YOU CAN'T CONCLUDE ANYTHING, GIVE US A PERFORMACE CONCLUSION, like which runs better with AA or AF? Which creates the best with both settings enabled?
Oh and AT. Remember back to the very first ATI 9700 Pro, you did tests with 6x AA and 16 AF. DO IT AGAIN. I want to see which is faster and better quality when their settings are absoulutely maxed out. Because I prefer playing 1024*768 at 6x AA and 16 AF then 1600*1200 at 4x AA 8x AF because I have a small moniter.
I am VERY disappointed in this article. You say Nvidia has cleaned up their act, but you don't prove anything conclusive as to why. You say they are similar but don't say why. The D3D AF Tester was totally different for the different levels. WHAT DOES THIS MEAN? Come on Anand clean up this article, it's very poorly designed and concluded and is not at all like your other GPU articles.
retrospooty - Thursday, December 11, 2003 - link
Well a Sony G500 is pretty good in my book =)Hanners - Thursday, December 11, 2003 - link
Not a bad article per se - Shame about the mistakes in the filtering section and the massive jumping to conclusions regarding Halo.gordon151 - Thursday, December 11, 2003 - link
I'm with #6 and the sucky monitor theory :P.Icewind - Thursday, December 11, 2003 - link
Or your monitor sucks #5ATI wins either way