GeForce 256

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GeForce 256
Geforce256logo.jpg VisionTek GeForce 256.jpg
Top: Logo
Bottom: Nvidia GeForce 256
Release dateOctober 11, 1999;24 years ago (October 11, 1999) (SDR)
December 13, 1999;24 years ago (December 13, 1999) [1] (DDR)
CodenameNV10
Architecture Celsius
Fabrication process TSMC 220 nm (CMOS)
Cards
Mid-rangeGeForce 256 SDR
High-endGeForce 256 DDR
API support
DirectX Direct3D 7.0
OpenGL OpenGL 1.2.1 (T&L)
History
Predecessor RIVA TNT2
Successor GeForce 2 series
Support status
Unsupported

The GeForce 256 is the original release in Nvidia's "GeForce" product line. Announced on August 31, 1999 and released on October 11, 1999, the GeForce 256 improves on its predecessor (RIVA TNT2) by increasing the number of fixed pixel pipelines, offloading host geometry calculations to a hardware transform and lighting (T&L) engine, and adding hardware motion compensation for MPEG-2 video. It offered a notably large leap in 3D PC gaming performance and was the first fully Direct3D 7-compliant 3D accelerator.

Contents

The chip was manufactured by TSMC using its 220 nm CMOS process. [2] There are two versions of the GeForce 256 the SDR version released in October 1999 and the DDR version released in mid-December 1999 each with a different type of SDRAM memory. The SDR version uses SDR SDRAM memory from Samsung Electronics, [3] [4] while the later DDR version uses DDR SDRAM memory from Hyundai Electronics (now SK Hynix). [5] [6]

Architecture

GeForce 256 (NV10) GPU KL NVIDIA Geforce 256.jpg
GeForce 256 (NV10) GPU
Quadro (NV10GL) GPU Quadro NV10GL GPU.jpg
Quadro (NV10GL) GPU
Die shot of an NV10 GPU NVIDIA@220nm@Fixed-pipline@NV10@GeForce 256@T5A3202220008 S1 Taiwan A Stack-DSC04167-DSC04189 - ZS-DMap-1 (30217645675).jpg
Die shot of an NV10 GPU

GeForce 256 was marketed as "the world's first 'GPU', or Graphics Processing Unit", a term Nvidia defined at the time as "a single-chip processor with integrated transform, lighting, triangle setup/clipping, and rendering engines that is capable of processing a minimum of 10 million polygons per second". [7] [8]

The "256" in its name stems from the "256-bit QuadPipe Rendering Engine", a term describing the four 64-bit pixel pipelines of the NV10 chip. In single-textured games NV10 could put out 4 pixels per cycle, while a two-textured scenario would limit this to 2 multitextured pixels per cycle, as the chip still had only one TMU per pipeline, just as TNT2. [9] In terms of rendering features, GeForce 256 also added support for cube environment mapping [9] and dot-product (Dot3) bump mapping. [10]

The integration of the transform and lighting hardware into the GPU itself set the GeForce 256 apart from older 3D accelerators that relied on the CPU to perform these calculations (also known as software transform and lighting). This reduction of 3D graphics solution complexity brought the cost of such hardware to a new low and made it accessible to cheap consumer graphics cards instead of being limited to the previous expensive professionally oriented niche designed for computer-aided design (CAD). NV10's T&L engine also allowed Nvidia to enter the CAD market with dedicated cards for the first time, with a product called Quadro. The Quadro line uses the same silicon chips as the GeForce cards, but has different driver support and certifications tailored to the unique requirements of CAD applications. [11]

Product comparisons

Compared to previous high-end 3D game accelerators, such as 3dfx Voodoo3 3500 and Nvidia RIVA TNT2 Ultra, GeForce provided up to a 50% or greater improvement in frame rate in some games (ones specifically written to take advantage of the hardware T&L) when coupled with a very-low-budget CPU. The later release and widespread adoption of GeForce 2 MX/4 MX cards with the same feature set meant unusually long support for the GeForce 256, until approximately 2006, in games such as Star Wars: Empire at War or Half-Life 2, the latter of which featured a Direct3D 7-compatible path, using a subset of Direct3D 9 to target the fixed-function pipeline of these GPUs.

Without broad application support at the time, critics pointed out that the T&L technology had little real-world value. Initially, it was only somewhat beneficial in certain situations in a few OpenGL-based 3D first-person shooters, most notably Quake III Arena . Benchmarks using low-budget CPUs like the Celeron 300A would give favourable results for the GeForce 256, but benchmarks done with some CPUs such as the Pentium II 300 would give better results with some older graphics cards like the 3dfx Voodoo 2. 3dfx and other competing graphics-card companies pointed out that a fast CPU could more than make up for the lack of a T&L unit. Software support for hardware T&L was not commonplace until several years after the release of the first GeForce. Early drivers were buggy and slow, while 3dfx cards enjoyed efficient, high-speed, mature Glide API and/or MiniGL support for the majority of games. Only after the GeForce 256 was replaced by the GeForce 2, and ATI's T&L-equipped Radeon was also on the market, did hardware T&L become a widely utilized feature in games.

The GeForce 256 was also quite expensive for the time and didn't offer tangible advantages over competitors' products outside of 3D acceleration. For example, its GUI and video playback acceleration were not significantly better than that offered by competition or even older Nvidia products. Additionally, some GeForce cards were plagued with poor analog signal circuitry, which caused display output to be blurry.[ citation needed ]

As CPUs became faster, the GeForce 256 demonstrated that the disadvantage of hardware T&L is that, if a CPU is fast enough, it can perform T&L functions faster than the GPU, thus making the GPU a hindrance to rendering performance. This changed the way the graphics market functioned, encouraging shorter graphics-card lifetimes and placing less emphasis on the CPU for gaming.

Motion compensation

The GeForce 256 introduced [12] motion compensation as a functional unit of the NV10 chip, [13] [14] this first-generation unit would be succeeded by Nvidia's HDVP (High-Definition Video Processor) in GeForce 2 GTS.

Specifications

Discontinued support

NVIDIA has ceased driver support for the GeForce 256 series.

VisionTek GeForce 256 DDR VisionTek GeForce 256.jpg
VisionTek GeForce 256 DDR

Final drivers

Product Support List Windows 95/98/Me – 71.84.
Product Support List Windows XP/2000 – 71.84.

The drivers for Windows 2000/XP may be installed on later versions of Windows such as Windows Vista and 7; however, they do not support desktop compositing or the Aero effects of these operating systems.

Competitors

See also

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References

  1. IGN staff (December 13, 1999). "News Briefs". Archived from the original on September 1, 2000. Retrieved October 1, 2020.
  2. Singer, Graham (April 3, 2013). "History of the Modern Graphics Processor, Part 2". TechSpot. Retrieved July 21, 2019.
  3. "NVIDIA GeForce 256 SDR". VideoCardz.net. Retrieved July 10, 2019.
  4. "K4S161622D Datasheet". Samsung Electronics . Retrieved July 10, 2019.
  5. "NVIDIA GeForce 256 DDR". VideoCardz.net. Retrieved July 10, 2019.
  6. "HY5DV651622 Datasheet" (PDF). Hynix . Retrieved July 10, 2019.
  7. "nVidia unveils new computer graphics accelerator". CNNfn . August 31, 1999.
  8. "Graphics Processing Unit (GPU)". www.nvidia.com. December 17, 2009. Retrieved March 24, 2016.
  9. 1 2 Shimpi, Anand Lal. "NVIDIA GeForce 256 Part 1: To buy or not to buy". www.anandtech.com.
  10. February 2001, Thomas Pabst 27 (February 27, 2001). "High-Tech And Vertex Juggling – NVIDIA's New GeForce3 GPU". Tom's Hardware.{{cite web}}: CS1 maint: numeric names: authors list (link)
  11. "Nvidia Workstation Products". Nvidia.com. Retrieved October 2, 2007.
  12. "ActiveWin.Com: NVIDIA GeForce 4 Ti 4600 – Review". www.activewin.com.
  13. "Technology brief" (PDF). www.orpheuscomputing.com. Retrieved September 21, 2020.
  14. "History of the Modern Graphics Processor, Part 2". TechSpot.
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