As the importance of multimedia and then 3D graphics has increased, the role of the graphics card has become ever more important and it has evolved into a highly efficient processing engine which can really be viewed as a highly specialised co-processor. By the late 1990s the rate of development in the graphics chip arena had reached levels unsurpassed in any other area of PC technology, with the major manufacturers such as 3dfx, ATI, Matrox, nVidia and S3 working to a barely believable six-month product life cycle! One of the consequences of this has been the consolidation of major chip vendors and graphics card manufacturers. Chip maker 3dfx started the trend in 1998 with the its acquisition of board manufacturer STB systems. This gave 3dfx a more direct route to market with retail product and the ability to manufacture and distribute boards that bearing its own branding.
Rival S3 followed suit in the summer of 1999 by buying Diamond Mulitmedia, thereby acquiring its graphics and sound card, modem and MP3 technologies. A matter of weeks later, 16-year veteran Number Nine announced its abandonment of the chip development side of its business in favour of board manufacturing. The consequence of all this manoeuvring was to leave nVidia as the last of the major graphics chip vendors without its own manufacturing facility – and the inevitable speculation of a tie-up with close partner, Creative Labs. Whilst there’d been no developments on this front by mid-2000, nVidia’s position in had been significantly strengthened by S3’s sale of its graphics business to VIA Technologies in April of that year. The move – which S3 portrayed as an important step in the transformation of the company from a graphics focused semiconductor supplier to a more broadly based Internet appliance company – left nVidia as sole remaining big player in the graphics chip business. Resolution is a term often used interchangeably with addressability, but it more properly refers to the sharpness, or detail, of the visual image.
It is primarily a function of the monitor and is determined by the beam size and dot pitch (sometimes referred to as ‘line pitch’). An image is created when a beam of electrons strikes phosphors which coat the base of the monitor’s ‘screen’. A group comprising one red, one green and one blue phosphor is known as a pixel. A pixel represents the smallest piece of the screen that can be controlled individually, and each pixel can be set to a different colour and intensity. A complete screen image is composed of thousands of pixels and the screen’s resolution – specified in terms of a row by column figure – is the maximum number of displayable pixels.
The higher the resolution, the more pixels that can be displayed and therefore the more information the screen can display at any given time. Resolutions generally fall into predefined sets and the table below shows the series of video standards since CGA, the first to support colour/graphics capabilityAll SVGA standards support the display of 16 million colours, but the number of colours that can be displayed simultaneously is limited by the amount of video memory installed in a system. The greater number of colours, or the higher the resolution or, the more video memory will be required. However, since it is a shared resource reducing one will allow an increase in the other. Each pixel of a screen image is displayed using a combination of three different colour signals: red, green and blue.
The precise appearance of each pixel is controlled by the intensity of these three beams of light and the amount of information that is stored about a pixel determines its colour depth. The more bits