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Graphics Programming Software IT Technology

GPU Gems 2 Gets Call for Participation 11

An anonymous reader writes "Following the publication of GPU Gems: Programming Techniques, Tips, and Tricks for Real-Time Graphics, NVIDIA has decided to produce a second GPU Gems volume in order to showcase the best new ideas and techniques for the latest programmable GPUs. Tentatively titled GPU Gems II: Techniques for Graphics and Compute Intensive Programming, NVIDIA is looking for innovative ideas from developers who are using GPUs in new ways to create stunning graphics and cutting-edge applications. GPU Gems II will have an increased focus on chapters exploring non-graphics applications of the computational capabilities of GPU hardware (learn more at www.GPGPU.org). If you would like to participate, please read through the submission guidelines and send an e-mail to articlesubmissions@nvidia.com with your proposed chapter title as the subject line, and the required description in the e-mail body. The deadline for submissions is Monday, August 16, 2004."
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GPU Gems 2 Gets Call for Participation

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  • 64 bit calculation (Score:4, Interesting)

    by Ann Coulter ( 614889 ) on Thursday July 29, 2004 @06:28AM (#9829972)
    What would really spike my interest is if GPU makers would add 64 bit floating point intensities to their GPUs. By that I mean that color components would be 64 bits instead of the current maximum of 32 bits. This would allow for us to produce very fast computational libraries based around the GPU with the full precision we have come to expect from existing libraries. The current 32 bits, which is actually 24 bits if you really consider that only the mantissa counts toward precision, is not enough for certain applications. We need 52 bit mantissas especially for polished results. By the way, it is not that hard to implement 64 bit calculations into the GPU. So in essense, general numerical analysis, and especially linear algebra, will greatly benefit from the implementation of a relatively uninteresting detail to most. Having 64 bit color intensities will not give any great enhancement in visual quality as we would use our GPUs for in the usual case. Although the immediate visual benefit is negligible, processing of visual data requires a lot more precision than the presentation precision. For example, brightening a scene will require low order bits to come forth. If the precision is limited, aliasing will occur. So there is an immediate benefit to higher precision 64 bit GPUs. The benefits of high precision intensities all revolve around processing, something that GPUs are becoming more and more adept at starting with the introduction of shader technology. In closing, 64 bit intensities only increase manufacturing costs by a small amount while providing great benefits to processing applications. I would believe that we will definitely have 64 bit super-parallel processors (such as a GPU) in the future (hopefully the near future). Having 64 bits is sufficient for most numerical analysis applications used in physical problems. However, 32 bits is not always sufficient. Therefore, the scientific field will most likely demand the introduction of super-parallel 64 bit processors when it becomes well know the benefits of super-parallel processing as opposed to the more traditional processing with our CPUs. I hope to see GPUs with 64 bit intensities as it is the logical step into the future of super-parallel processing.
    • However.. it would negatively impact the performance for those of us who want to use the card just to make graphics, where 24 bits of precision isn't all that bad.

      You'd have to add at least another stage to every comparator, adder, etc, and that doesn't just use up more silicon.. that also increases latencies.

    • i'm really talking out of my ass here, but i remember a paper that discussed using n single-precision values to simulate higher precision. Couldn't you do that with multiple passes?
      • you can always fake precision if you want to badly enough, but it's really slow. One arithmetic operation vs. many, not to mention the various memory accesses that may need to happen, depending on how it's implemented.

        Also talking out of my ass. :)
    • I wouldn't hold my breath. It was hard enough to convince manufacturers that floating-point frame buffers and textures were needed in the first place.

      Even now, only the NV40 offers what you could honestly call single-precision floats. The ATI cards give you 24 bits for the whole value.
    • by Shinobi ( 19308 )
      The GeForce 6800 series can actually handle 64-bit floating point calculations.
    • this goes against the entire point of the GPU.

      32 bits is enough for a GPU. why? the point of a GPU is to produce good-looking graphics fast. precision problems with single precision IEEE754s are by and large far too small to notice once the end result is shipped off to a screen as color. so, 64 bits is killing a fly with a sledgehammer in a GPU.

      the brightening example holds no water. 24 bits of intensity precision, mapped to the gamut of a crt or lcd, is orders of magnitude more than necessary for ext

      • You just spent a lot of words being wrong. 32 bits are NOT enough for GPUs and gaming. 32 bit is plenty fine when you're talking about a single texture, but when you're doing 10-20 passes to do textures, normal maps, lighting, etc, you start seeing rounding errors that accumulate giving you banding artifacts similar to those that were common when 16 bit color was king.

        In any case, the Nvidia 6800 does 64bit color NOW and 64bit is going to be pretty much standard equipement across the board within the ne

      • One of the most time consuming processes in image process is the FFT (Fast Fourier Transform) and theIFFT (Inverse Fast Fourier Transform). For digital images, the DFT (Discrete Fourier Transform) can be used instead. These are used to implement many types of image processing calculation (convolution, image sharpening/blurring and texture classification). However, due to precision requirements, all calculations must use 64-bit floating point values (doubles) in order to guarantee accuracy. Although, since e

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