AMD

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For other possible meanings of AMD see AMD (disambiguation)

Advanced Micro Devices, Inc. (AMD) (NYSE:AMD) is a manufacturer of integrated circuits based in Sunnyvale, California. It is the second-largest supplier of x86 compatible processors, and a leading supplier of non-volatile flash memory. It was founded in 1969 by a group of defectors from Fairchild Semiconductor, including the flashy Jerry Sanders.

AMD is best known for the Athlon, Opteron and Duron lines of x86-compatible processors. Their more general components have been found in early Apple computers and numerous other electronic devices.

Contents

1 Financial information

Financial information

AMD is publicly traded at NYSE with the symbol AMD. Its market capitalization was around US$5 billion at the end of 2003.

History

The company started as a producer of logic chips in 1969 and entered the RAM chip business in 1975. That same year, it introduced a reverse-engineered clone of the Intel 8080 microprocessor.

In February 1982, AMD signed a contract with Intel, becoming a licensed second-source manufacturer of the 8086 and 8088 processors. IBM wanted to use the Intel 8088 in its IBM PC, but IBM's policy at the time was to require at least two sources for its chips.

AMD later produced the 80286, or 286, under the same arrangement, but then Intel cancelled the agreement in 1986. The growing popularity of the PC clone market meant Intel could produce CPUs on its terms, rather than IBM's.

In 1991, AMD released the Am386, its clone of the later Intel 80386 processor. It took less than a year for AMD to sell a million units. AMD followed in 1993 with the Am486. Both sold at a significantly lower price than the Intel versions. Intel challenged AMD's right to produce these chips in court, but ultimately lost its case. The two competitors have had full cross-licensing agreements for patents and some copyrights from the very start: each partner can use the other's technological innovations without charge. AMD's 386DX-40 was very popular with smaller, independent clone manufacturers, and the Am486 was used by a number of large OEMs, including Compaq.

During this time, AMD attempted to embrace the perceived shift towards RISC with their own AMD 29K processor (based on a bitslice computational model), and they attempted to diversify into graphics and audio devices as well as flash memory. While the AMD 29K survived as an embedded processor and AMD continues to make industry leading flash memory, AMD was not as successful with its other endeavours. AMD decided to switch gears and concentrate solely on Intel compatible microprocessors and flash memory. This put them in direct competition with Intel for x86 compatible processors and their flash memory secondary markets.

Their first completely in-house processor was the K5, launched very belatedly in 1995. The "K" was a reference to "Kryptonite". It was intended to compete directly with the Intel Pentium CPU, which had been released in 1993, but architecturally it had more in common with the newly-released Pentium Pro than the Pentium or Cyrix's 6x86. There were a number of problems however; a confusing naming system was employed, with some chips being represented by their true core speed, others with a PR number. More tellingly, the K5 couldn't match the 6x86's integer performance, nor the Pentium's FPU performance. This, combined with the large die size and the fact that the design scaled badly, doomed the K5 to near-total failure in the market place. To its credit, however, the K5 didn't suffer from the compatibility problems that the 6x86 did, and it didn't run as hot as Cyrix's chip.

In 1996, AMD purchased NexGen, Inc. and the rights to intellectual property behind their Nx series of x86 compatible processors. In a year, they reworked the Nx686 microarchitecture and branded it the K6. NexGen's original design had never made it to market. The redesign included a feedback dynamic instruction reording mechanism, and MMX instructions. Most importantly AMD made it pin-compatible with Intel's Pentium, enabling it to be used in the widely available "Socket 7" based motherboards. Like the Nx686 and Nx586 before it, the K6 translated the Pentium compatible x86 instruction set to RISC-like micro-instructions. In the following year, AMD released the K6-2 which added a set of floating point multimedia instructions called 3DNow!, as well as a new socket standard called "Super Socket 7" both of which delivered enhanced performance.

In January 1999, the final iteration of the K6-x series, the 450 MHz K6-III, was extremely competitive with Intel's top of the line chips. This chip was essentially a K6-2 with 256 kilobytes of full-speed level 2 cache integrated into the core and a better branch prediction unit. While it matched (generally beating) the Pentium II/III in integer operations, the FPU was a non-pipelined serial design and could not compete with Intel's more advanced FPU architecture. Although 3DNow! could theoretically compensate for this weakness, few game developers made use of it, the most notable exception being id Software's Quake 2.

Throughout its lifetime, the K6 processor came close, but never quite seemed to equal the performance of processor offerings from Intel. Furthermore, the motherboards that worked with the K6 were of varying quality, and AMD had process manufacturing difficulties which affected some shipments. AMD gained a reputation of making a somewhat slower and less reliable "x86 clone" even though the performance difference was slight and the best K6 compatible motherboards were very reliable. This forced AMD into a position of selling their K6 processors at a substantial discount versus Intel's P6 core based processors, the Pentium II and the Pentium III. Intel responded to AMD's lower prices with the "Celeron" version of their Pentiums which were cheaper and slower in a partially successful attempt to capture marketshare.

In August of 1999, AMD released the Athlon (K7) processor. The Athlon had an advanced micro-architecture geared towards overall performance. The timing of the release of this processor put it at a great performance advantage versus Intel's P6 core based processors (which culminated as their mainline processor in the Pentium III.) The Intel P6 core was nearing the end of its life-cycle, while the Athlon was just getting started. Objectively, the Athlon had higher "per clock" architectural performance versus the comparable Intel P6 core based parts, as well as higher frequencies. AMD announced a 1GHz Athlon in early March 2000 and delivered them in that same month. Intel also announced a 1Ghz Pentium a few days later, but did not ship them in significant volume until June of that year.

AMD also worked hard to increase the reliability and performance of motherboards for the Athlon. They also improved the discipline and predictability of their manufacturing process. AMD also released a second line of processors based on the Athlon core called the Duron which was a slower and cheaper version of the processor aimed at competing against the still-shipping Celeron processor, providing some insulation for the Athlon against AMD's prior reputation for only making cheaper and slower "Intel clones". The combination of these technical and marketing successes did much to repair and bolster AMD's reputation for making high-performance CPUs that shipped and worked reliably. AMD continued to undercut Intel on price which helped them establish up to 20% market share.

In 2001, Intel released the Pentium 4 architecture (code-named Willamette) which had a radically different microarchitecture than the Athlon or the P6 cores. While sporting a dramatically higher clock rate, the per-clock architectural performance of the Pentium 4 appears to be much slower than the Athlon or even Intel's own P6 core based processors. This lead some to believe that the Pentium 4 had higher performance because of its higher clock rate, despite benchmark performance.

AMD responded with a new K7 core (code-named Palomino) which had superior memory pre-fetching mechanisms, SSE (a set of floating-point extensions first featured on the Pentium III), an on-chip L2 cache and also re-branded them based on Model numbers which would approximately project the clock rate relative performance of these new Athlons versus the earliest versions of the Athlon. The net effect of this was for the Model numbers to be more comparable to the Pentium 4's actual clock rate. For AMD processors of a given Model number, the comparable Pentium 4 by corresponding clock rate showed rough parity on performance in a wide variety of benchmarks.

Intel countered AMD and its Athlon by ramping the Pentium 4 clock rate aggressively in its early lifetime, just as the Athlon was nearing its end of life, giving it a brief period of performance dominance. AMD responded with the "Thoroughbred" Athlon XP, essentially a 130 nanometre version of the Palomino. AMD later introduced the "Barton" core, which increased the L2 cache to 512 KiB.

AMD64

AMD's future strategy is shown with the 64-bit AMD64 "Hammer" architecture (a.k.a. K8), based on the AMD Opteron. Whilst retaining support for the traditional x86 instruction set, the Hammer's native 64-bit mode is unique to AMD processors and incompatible with the IA-64 architecture used in Intel's Itanium processor (Intel has since announced an extension to their Xeon CPU based on and compatible with AMD64 known as EM64T). As a relatively straightforward extension and cleanup of the basic x86 architecture, from a technical perspective AMD's conservative approach looks likely to produce, at least initially, better price-performance than the Itanium and its successors.

This also gives AMD a marketing advantage in that it can leverage its ordinary 32-bit x86 processor market to naturally upgrade and adopt its 64-bit processors without introducing risk to the existing software infrastructure. The potential for this processor to compete with Itanium head on in its intended markets (high-end 64 bit servers) remains unclear.

AMD released its first AMD64 processor (K8), the Opteron, in March 2003. The Opteron is designed for workstation and server systems, including those containing more than one processor. However, Cray Inc. announced that it was going to use the Opteron as the basis for a top of the line super computer called "Red Storm", indicating that there seemed to be no limit for what sort of applications the Opteron could be used for. AMD then released Athlon 64 and Athlon 64 FX in September 2003 based on the same core architecture, which most benchmarks indicated both as performing equal or better than the Pentium 4. The Pentium 4 was previously a boon to Athlon 64, and had retained its performance advantage in streaming media processing applications. As of November 2004, there had been the 2700+, 2800+, 3000+, 3200+, 3400+, 3700+, 3800+, and 4000+ for the Athlon 64.

The AMD Athlon FX and the Opteron use a different numbering system. The Opteron includes three series, the 100's, 200's, and the 800's, each of which are meant for different types of servers and workstations. 100 Series Opterons are intended for Workstation, and uniprocessor configuration. The 200 series are intended for workstation or server use, and are not qualified to use more than 2 processors in the same system. 800 Series Opterons are used in 4 or 8 way (CPU) servers which anchor some of the most powerful computers built using Opteron. The Athlon 64 FX uses numbers going up, starting with 51. The three models available for the high-end Athlon FX include the FX-51, FX-53 and the FX-55. The recent release of the Athlon 64 FX-55 has shown that up against the Pentium 4 Extreme Edition, you can't loose if you have the cash to spend on one, as the Pentium 4 Extreme Edition looses out on many categories that it previously held the crown in (like Media Encoding or Adobe Premiere) AMD thus regains the crown in those areas once again. The Hammer core is very similar to the Athlon in basic microarchitecture, but includes 4 major differences:

The inclusion of the AMD64 instruction set;
A built-in DDR memory controller;
The HyperTransport point-to-point-bus.
Support for the NX, or No-Execute bit, which serves to act as a hardware buffer against viruses and other software exploits.

These improve both the capabilities and performance of the Hammer versus the K7 Athlon.

Geode

In August 2003 AMD also purchased the Geode business (originally the Cyrix MediaGX) from National Semiconductor to augment its existing line of embedded x86 processor products. During the 2nd Quarter of 2004, it planned to launch new low-power Geodes with speeds just over 1 GHz

External link

Official info:

AMD Corporate Website