Influence of the IBM PC on the personal computer market
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Following the introduction of the IBM Personal Computer, or IBM PC, many other personal computer architectures became extinct within just a few years.[1]
Contents
Before the IBM PC's introduction
Before the IBM PC was introduced, the personal computer market was dominated by systems using the 6502 and Z80 8-bit microprocessors, such as the TRS 80, Commodore PET and Apple II series, which used proprietary operating systems,[2] and by computers running CP/M. After IBM introduced the IBM PC, it was not until 1984 that IBM PC and clones became the dominant computers.[3] In 1983, Byte forecast that by 1990, IBM would command only 11% of business computer sales. Commodore was predicted to hold a slim lead in a highly competitive market, at 11.9%.[4]
Around 1978, several 16-bit CPUs became available. Examples included the Data General mN601, Fairchild's 9440, the Ferranti F100-1, the General Instrument CP1600 and CP1610, the National Semiconductor INS8900, Panafacom's MN1610,[5] Texas Instruments' TMS9900, and, most notably, the Intel 8086. These new processors were expensive to incorporate in personal computers, as they used a 16-bit data bus and needed rare (and thus expensive) 16-bit peripheral and support chips.
More than 50 new business-oriented personal computer systems came on the market in the year before IBM released the IBM PC.[6][7] Very few of them used a 16- or 32-bit microprocessor, as 8-bit systems were generally believed by the vendors to be perfectly adequate, and the Intel 8086 was too expensive to use.[8]
Some of the main manufacturers selling 8-bit business systems during this period were
- Apple Computer Inc.
- Commodore International
- Cromemco
- Digital Equipment Corporation
- Durango Systems inc.
- Hewlett-Packard
- Intersystems
- Morrow Designs
- North Star Computers
- Ohio Scientific
- Olivetti
- Processor Technology
- Sharp
- South West Technical Products Corporation
- Tandy Corporation
- Zenith Data Systems/Heathkit
The IBM PC
On August 12, 1981, IBM released the IBM Personal Computer.[9] The IBM PC used the then-new Intel 8088 processor. Like other 16-bit CPUs, it could access up to 1 megabyte of RAM, but it used an 8-bit-wide data bus to memory and peripherals. This design allowed use of the large, readily available, and relatively inexpensive family of 8-bit-compatible support chips. IBM decided to use the Intel 8088 after first considering the Motorola 68000 and the Intel i8086, because the other two were considered to be too powerful for their needs.[10][11] Although already established rivals like Apple and Radio Shack had many advantages over the company new to microcomputers,[12] IBM's reputation in business computing allowed the IBM PC architecture to take a substantial market share of business applications,[13][14] and many small companies that sold IBM-compatible software or hardware rapidly grew in size and importance, including Tecmar, Quadram, AST Research, and Microsoft.[15]:{{{3}}}
As of mid-1982 three other mainframe and minicomputer companies sold microcomputers, but unlike IBM Hewlett-Packard, Xerox, and Control Data Corporation chose the CP/M operating system.[16] Many other companies made "business personal computers" using their own proprietary designs, some still using 8-bit microprocessors. The ones that used Intel x86 processors often used the generic, non-IBM-compatible specific version of MS-DOS or CP/M-86, just as 8-bit systems with an Intel 8080 compatible CPU normally used CP/M.
The use of MS-DOS on non-IBM PC compatible x86-based systems
“ | [Bill] Gates predicts that in the next six to nine months, several 8086 machines will be introduced. Just because a machine is based on the same processor, he explains, does not mean that all PC software will run on it. In some cases, software bypasses the operating system and uses specific hardware characteristics of the PC. | ” |
— InfoWorld, 23 August 1982[17]:{{{3}}} |
Within a year of the IBM PC's introduction, Microsoft licensed MS-DOS to over 70 other companies.[17] One of the first computers to achieve 100% PC compatibility was the Compaq portable, released in November 1982;[18] it remained the most compatible clone into 1984.[19]:{{{3}}} When the PC did not yet dominate the market, however, most x86-based systems were not clones of the IBM PC design, but had different internal designs, like the CP/M-based 8-bit systems that preceded them.
The IBM PC was difficult to obtain for several years after its introduction. Many makers of MS-DOS computers intentionally avoided full IBM compatibility because they expected that the market for what InfoWorld described as "ordinary PC clones" would decline once the shortage of real PCs ended. They feared the fate of companies that sold computers plug-compatible with IBM mainframes in the 1960s and 1970s—many of which went bankrupt after IBM changed specifications—and believed that a market existed for personal computers with a similar selection of software to the IBM PC, but with better hardware.[19]:{{{3}}}
Even a few years after the IBM PC's introduction, manufacturers such as Digital, HP, Sanyo, Tandy, Texas Instruments, Tulip Computers, NEC, Wang Laboratories, and Xerox continued to introduce personal computers that were barely, if at all, compatible with the IBM PC, even though they used x86 processors and ran MS-DOS. They used MS-DOS the way Microsoft had originally envisioned: In the same way as 8-bits systems used CP/M. They implemented standard ROM BIOS routines to achieve hardware independence as had 8080 (Z80) compatibles. So each machine had a different BIOS that, as long as software made only standard MS-DOS calls, would ensure compatibility.
While Microsoft used a sophisticated installer with its DOS programs like Multiplan that provided device drivers for many non IBM PC-compatible computers, most other software vendors did not.[19]:{{{3}}}[20] Columbia University discussed the difficulty of having Kermit support many different clones and MS-DOS computers.[21] Peter Norton, who earlier had encouraged vendors to write software that ran on many different computers, by early 1985 admitted—after experiencing the difficulty of doing so while rewriting Norton Utilities—that "there's no practical way for most software creators to write generic software".[22] Dealers found carrying multiple versions of software for clones of varying levels of compatibility to be difficult.[19]
To get the best results out of the 8088's modest performance, many popular software applications were written specifically for the IBM PC. The developers of these programs opted to write directly to the computer's (video) memory and peripheral chips, bypassing MS-DOS and the BIOS. For example, a program might directly update the video refresh memory, instead of using MS-DOS calls and device drivers to alter the appearance of the screen. Many notable software packages, such as the spreadsheet program Lotus 1-2-3, and Microsoft's Microsoft Flight Simulator 1.0, directly accessed the IBM PC's hardware, bypassing the BIOS, and therefore did not work on computers that were even trivially different from the IBM PC. This was especially common among games. As a result, the systems that were not fully IBM PC-compatible couldn't run this software, and quickly became obsolete. Rendered obsolete with them was the CP/M-inherited concept of OEM versions of MS-DOS meant to run (through BIOS calls) on non IBM-PC hardware.
Cloning the PC BIOS
In 1984 Phoenix Technologies began licensing its clone of the IBM PC BIOS. The Phoenix BIOS and competitors such as AMI BIOS made it possible for anyone to market a PC compatible computer,[23][24] without having to develop a compatible BIOS like Compaq.
Decline of the Intel 80186
Although based on the i8086 and enabling the creation of relatively low-cost x86-based systems, the Intel 80186 quickly lost appeal for x86-based PC builders because the supporting circuitry inside the Intel 80186 chip was incompatible with those used in the standard PC chipset as implemented by IBM. It was very rarely used in personal computers after 1982.
Domination of the clones
"Is it PC compatible?"
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Imagine that Cray computer decides to make a personal computer. It has a 100 MHz processor, 20 megabytes of RAM, 500 megabytes of disk storage, a screen resolution of 1024 X 1024 pixels, relies entirely on voice recognition for input, fits in your shirt pocket and costs $3,000. What's the first question that the computer community asks? "Is it PC compatible?"
— InfoWorld, February 1984[25]
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You don't ask whether a new machine is fast or slow, new technology or old. The first question is, "Is it PC compatible?"
— Creative Computing, November 1984[15]
In February 1984 BYTE described how "the personal computer market seems to be shadowed under a cloud of compatibility: the drive to be compatible with the IBM Personal Computer family has assumed near-fetish proportions", which it stated was "inevitable in the light of the phenomenal market acceptance of the IBM PC".[26] The magazine cited the announcement by North Star in fall 1983 of its first PC-compatible microcomputer. Founded in 1976, North Star had long been successful with 8-bit S-100 bus products, and had introduced proprietary 16-bit products, but now the company acknowledged that the IBM PC had become a "standard", one which North Star needed to follow. BYTE described the announcement as representative of the great impact IBM had made on the industry:[27]
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It's become painfully obvious that the key to survival as a major manufacturer is acceptance by the business community. The IBM PC has unquestionably open the door to that market wider than any personal computer before it, but in so doing has made compatibility a primary factor in microcomputer design, for better or for worse. Recent announcements by North Star ... and a host of smaller firms seem to indicate that the 8088/MS-DOS/IBM-compatible bandwagon is becoming much more like a speeding freight train.
The magazine expressed concern that "IBM's burgeoning influence in the PC community is stifling innovation because so many other companies are mimicking Big Blue".[26]:{{{3}}} Admitting that "it's what our dealers asked for", Kaypro also introduced the company's first IBM compatible that year.[28] Four years after Tandy's Jon Shirley predicted to InfoWorld that the new IBM PC's "major market would be IBM addicts",[29] the magazine in 1985 similarly called the IBM compatibility of the Tandy 1000 "no small concession to Big Blue's dominating stranglehold" by a company that had been "struggling openly in the blood-soaked arena of personal computers".[30] IBM's mainframe rivals, the BUNCH, introduced their own compatibles,[31] and when Hewlett-Packard introduced the Vectra InfoWorld stated that the company was "responding to demands from its customers for full IBM PC compatibility".[32]
“ | I believe that the era when a machine could be introduced successfully into the marketplace with a total dearth of software ended abruptly with the Macintosh. And those days will not return. | ” |
— Creative Computing, February 1985[33] |
Mitch Kapor of Lotus Development Corporation said in 1984 that "either you have to be PC-compatible or very special".[34] "Compatibility has proven to be the only safe path", Microsoft executive Jim Harris stated in 1985,[35]:{{{3}}} while InfoWorld wrote that IBM's competitors were "whipped into conformity" with its designs, because of "the total failure of every company that tried to improve on the IBM PC".[36] Customers only wanted to run PC applications like 1-2-3, and developers only cared about the massive PC installed base, so any non-compatible—no matter its technical superiority—from a company other than Apple failed for lack of customers and software.[25]:{{{3}}} Compatibility became so important that Dave Winer joked that year (referring to the PC AT's incomplete compatibility with the IBM PC), "The only company that can introduce a machine that isn't PC compatible and survive is IBM".[35]:{{{3}}}
By 1985 the shortage of IBM PCs had ended, causing financial difficulties for many vendors of compatibles; nonetheless, Harris said, "The only ones that have done worse than the compatibles are the noncompatibles."[35] By the end of the year PC Magazine stated that even IBM could no longer introduce a rumored proprietary, non-compatible operating system. Noting that the company's unsuccessful PCjr's "cardinal sin was that it wasn't PC compatible", the magazine wrote that "backward compatibility [with the IBM PC] is the single largest concern of hardware and software developers. The user community is too large and demanding to accept radical changes or abandon solutions that have worked in the past."[37]
Within a few years of the introduction of fully compatible PC clones, almost all rival business personal computer systems, and alternate x86 using architectures, were gone from the market. Despite the inherent dangers of an industry based on a de facto "standard",[38] a thriving PC clone industry emerged. The only other non-IBM PC-compatible systems that remained were those systems that were classified as home computers, such as the Apple II series, or business systems that offered features not available on the IBM PC, such as a high level of integration (e.g., bundled accounting and inventory)[clarification needed] or fault-tolerance and multitasking and multi-user features.
Wave of inexpensive clones
Compaq's prices were comparable to IBM's, and the company emphasized its PC compatibles' features and quality to corporate customers. From mid-1985, what Compute! described as a "wave" of inexpensive clones from American and Asian companies caused prices to decline; by the end of 1986, the equivalent to a $1600 real IBM PC with 256K RAM and two disk drives cost as little as $600, lower than the price of the Apple IIc. Consumers began purchasing DOS computers for the home in large numbers; Tandy estimated that half of its 1000 sales went to homes, newcomer Leading Edge Model D comprised 1% of the US home-computer market that year, and toy and discount stores sold a clone made by Hyundai like a stereo, without a demonstrator model or salesman.[39][40]:{{{3}}}[41]:{{{3}}}[42]:{{{3}}}[43]:{{{3}}}[44]
The inexpensive clones succeeded with consumers—who saw them as superior to lower-end game machines—where IBM failed two years earlier with the PCjr. Unlike the IBM product, they were as fast as or faster than the IBM PC and highly compatible so users could bring work home. Although as inexpensive as home computers of a few years earlier, and comparable in price to the Commodore Amiga, Atari ST, and Apple IIGS, consumers used clones for both spreadsheets and entertainment. Their popularity caused consumer-software companies to increase the number of IBM-compatible products; Electronic Arts, for example, began developing games specifically for the PC as opposed to conversions from other computers.[41][42][43][40]
At the January 1987 Consumer Electronics Show both Commodore and Atari announced their own clones.[45] By 1987 the PC industry was growing so quickly that the formerly business-only platform had become the largest and most important market for computer game companies, outselling games for the Apple II or Commodore 64. With the EGA video card, an inexpensive clone was better for games than the other computers.[46][47][48] By 1989 80% of readers of Compute! owned DOS computers,[49] and the magazine announced "greater emphasis on MS-DOS home computing".[50]
IBM's influence on the industry decreased, as competition increased and rivals introduced computers that improved on IBM's designs while maintaining compatibility. In 1986 the Compaq Deskpro 386 was the first computer based on the Intel 80386. In 1987 IBM unsuccessfully attempted to regain leadership of the market with the Personal System/2 line and proprietary MicroChannel Architecture.
Clones conquer the home
By 1990 Computer Gaming World told a reader complaining about the many reviews of PC games that "most companies are attempting to get their MS-DOS products out the door, first".[51] It reported that MS-DOS comprised 65% of the computer-game market, with the Amiga at 10%; all other computers, including the Macintosh, were below 10% and declining.[52] The Amiga and most others, such as the ST and various MSX2 computers, remained on the market until PC compatibles gained sufficient multimedia capabilities to compete with home computers. With the advent of inexpensive versions of the VGA video card and the Sound Blaster sound card (and its clones), most of the remaining home computers were driven from the market.
By 1995, other than the Macintosh, almost no new consumer-oriented systems were sold that were not IBM PC clones. The Macintosh originally used Motorola's 68000 family of processors, later migrating to the PowerPC architecture. Throughout the 1990s Apple would steadily transition the Macintosh platform from proprietary expansion interfaces to use standards from the PC world such as IDE, PCI and USB. In 2006, Apple converted the Macintosh to the Intel x86 architecture. Modern Macintosh computers are essentially IBM PC compatibles, capable of booting Microsoft Windows and running most IBM PC-compatible software, but still retain unique design elements that support Apple's Mac OS X operating system.
In 2008 Sid Meier listed the IBM PC as one of the three most important innovations in the history of videogames.[53]
Systems launched shortly after the IBM PC
Shortly after the IBM PC was released, an obvious split appeared between systems that opted to use an x86-compatible processor, and those that chose another architecture. Almost all of the x86 systems provided a version of MS-DOS. The others used many different operating systems, although the Z80-based systems typically offered a version of CP/M. The common usage of MS-DOS unified the x86-based systems, promoting growth of the x86/MS-DOS "ecosystem."
As the non-x86 architectures died off, and x86 systems standardized into fully IBM PC compatible clones, a market filled with dozens of different competing systems was reduced to a near-monoculture of x86-based, IBM PC compatible, MS-DOS systems.
x86-based systems (using OEM-specific versions of MS-DOS)
Early after the launch of the IBM PC in 1981, there were still dozens of systems that were not IBM PC-compatible, but did use Intel x86 chips.[54] They used Intel 8088, 8086, or 80186 processors, and almost without exception offered an OEM version of MS-DOS (as opposed to the OEM version customized for IBM's use). However, they generally made no attempt to copy the IBM PC's architecture, so these machines had different I/O addresses, a different system bus, different video controllers, and other differences from the original IBM PC. These differences, which were sometimes rather minor, were used to improve upon the IBM PC's design, but as a result of the differences, software that directly manipulated the hardware would not run correctly. In most cases, the x86-based systems that didn't use a fully IBM PC compatible design didn't sell well enough to attract support from software manufacturers, though a few computer manufacturers arranged for compatible versions of popular applications to be developed and sold specifically for their machines.
Fully IBM PC-compatible clones appeared on the market shortly thereafter, as the advantages of cloning became impossible to ignore. But before that some of the more notable systems that were x86-compatible, but not real clones, were:
- the ACT Apricot by ACT
- the Dulmont Magnum
- the Epson QX-16
- the Seequa Chameleon
- the HP-150 by Hewlett-Packard and the later HP 95LX, HP 100LX, HP 200LX, HP 1000CX, HP OmniGo 700LX, HP OmniGo 100, and HP OmniGo 120.
- the Hyperion by Infotech Cie used its own H-DOS OEM version of MS-DOS and was, for a time, to be manufactured by Commodore as its first PC compatibile.
- the MBC-550 by Sanyo had many differences, including non-interchangeability of diskettes and non-standard ROM location.
- the DG-One by Data General was an early laptop with full 80x25 LCD screen that could boot some generic DOSes but worked best with their OEM version of MS-DOS, and had some hardware incompatibilities (especially in the serial I-O chip) as part of the compromise to reduce power consumption. Later models were more compatible with generic PC clones.
- the DG/10 by Data General had two processors, one an Intel 8086, running a very-modified[55] version of MSDOS (alternatively: CP/M-86) in a patented closely coupled arrangement with Data General's own microECLIPSE (the 8086 "invisibly" calling the microECLIPSE whenever it needed access to some peripherals, such as disks, while the 8086 had control over other peripherals such as the screen).
- the 80186-based Mindset graphics computer
- the Morrow Designs' Morrow Pivot[56]
- the MZ-5500 by Sharp
- the Decision Mate V from NCR Corporation;[57][58] its version of MS-DOS was called NCR-DOS
- the MikroMikko_2 by Nokia
- the The NorthStar Advantage
- the PC-9800 and PC-9801 systems from NEC[59]
- the Rainbow 100 from DEC
- the RM Nimbus by RM plc
- the Tandy 2000 by RadioShack
- the Texas Instruments TI Professional[60]
- the Torch Graduate by Torch Computers
- the Tulip System-1 by Tulip
- the Victor 9000 by Sirius Systems Technology
- the :YES by Philips was late on the market, ran DOS Plus and MS-DOS, but by using an 80186 it was incompatible with IBM's PC
- the Z-100 by Zenith with an MS-DOS OEM version named Z-DOS
Non-x86-based systems
Not all manufacturers immediately switched to the Intel x86 microprocessor family and MS-DOS. A few companies continued releasing systems based on non-Intel architectures.[61]
Some of these systems used a 32-bit microprocessor, the most popular being the Motorola 68000. Others continued to use 8-bit microprocessors. Many of these systems were eventually forced out of the market by the onslaught of the IBM PC clones, although their architectures may have had superior capabilities, especially in the area of multimedia. The PC architectures of that era often only had a CGA display, and no other sound system than the internal PC speaker.
Three systems of this era, while now extinct, have thriving legacies:
- The Apple Lisa by Apple Inc. was the predecessor of the Apple Macintosh, inspiring the Macintosh's design. The original Macintosh used a Motorola 68000 chip like the Lisa, and had a sufficiently similar design that some Lisa systems were converted for sale as "Macintosh XL" computers.
- The Acorn Computers Acorn Archimedes, later named the Risc PC, used a custom-designed microprocessor: the ARM. The ARM architecture continues to be popular, appearing in nearly all mobile phones and in many hand-held devices like Apple's iPhone, iPod and iPad, as well as small UNIX-based systems. The Risc PC's descendants include the A9home, the Iyonix PC and the RiscStation R7500.[62]
- The Sun Microsystems Sun-1[63] and Sun-2 families of BSD UNIX systems introduced the SunOS UNIX operating system, running on Motorola 680x0 chips. Sun's current large-scale UNIX systems use the SPARC processor family developed by Sun, but run a descendant of System V called Solaris.
Other non-x86-based systems available at the IBM PC's launch
- the 8-bit Commodore PET and CBM series
- the Cromemco CS-1
- Intertec's Compustar II VPU Model 20[64]
- the Corvus Concept
- the Kaypro 10
- the Fujitsu Micro 16s[65]
- the Micro Decision by Morrow Designs[66]
- the MTU-130 by Micro Technology Unlimited[67]
- the Xerox 820
- the Epson QX-10
- the RoadRunner from MicroOffice[68]
- the TRS-80 models 16 and 16e and Tandy 6000 by Tandy Corporation.
See also
- Open architecture
- Timeline of DOS operating systems
- Comparison of DOS operating systems
- Wintel
- PC DOS
- History of computing hardware (1960s–present)
- IBM PC compatible
- De facto standard
- Dominant design
- List of machines running CP/M
References
- ↑ about the IBM-PC and its dominance in the market
- ↑ Lua error in package.lua at line 80: module 'strict' not found.
- ↑ http://arstechnica.com/business/2012/08/from-altair-to-ipad-35-years-of-personal-computer-market-share/2/
- ↑ Lua error in package.lua at line 80: module 'strict' not found.
- ↑ http://www.cpu-museum.com/161x_e.htm
- ↑ systems released in 1980
- ↑ systems released in 1981
- ↑ Lua error in package.lua at line 80: module 'strict' not found. The editors asked 17 personal computer executives "Is 8-bit dead?" The response was mixed. Gary Kildall, author of the CP/M operating system, said "We're not too concerned that 8-bit stuff is going to die." Bill Gates said "We need the power of the 16-bit computers for good software design."
- ↑ timeline of computing history 1981
- ↑ [1]
- ↑ THE 8088, FIRST INTEL'S REALLY SUCCESSFUL CPU (JUNE 1979) – an article about the influence of the i8088 on old-computers.com.
- ↑ Lua error in package.lua at line 80: module 'strict' not found.
- ↑ [2]
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- ↑ Lua error in package.lua at line 80: module 'strict' not found.
- ↑ 17.0 17.1 Lua error in package.lua at line 80: module 'strict' not found.
- ↑ Compaq portable
- ↑ 19.0 19.1 19.2 19.3 Lua error in package.lua at line 80: module 'strict' not found.
- ↑ Lua error in package.lua at line 80: module 'strict' not found.
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- ↑ Lua error in package.lua at line 80: module 'strict' not found.
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- ↑ Lua error in package.lua at line 80: module 'strict' not found.
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- ↑ Lua error in package.lua at line 80: module 'strict' not found.
- ↑ Lua error in package.lua at line 80: module 'strict' not found.
- ↑ search here with ms-dos as Operating System
- ↑ Lua error in package.lua at line 80: module 'strict' not found.
- ↑ Morrow Pivot 1
- ↑ NCR decision mate V
- ↑ [3]
- ↑ [4]
- ↑ TI-professional
- ↑ systems released in 1982, often non IBM-PC compatible
- ↑ Risc PC legacy site
- ↑ Sun 1 info
- ↑ Intertec CompuStar
- ↑ Fujitsu_Micro_16s
- ↑ morrow designs micro decision
- ↑ MTU-130
- ↑ MicroOffice RoadRunner