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Top 20 Small Systems
From soldering irons to SparcStations, from MITS to Macintosh, personal computers have evolved from do-it-yourself kits for electronics hobbyists into machines that practically leap out of the box and set themselves up. What enabled them to get from there to here? Innovation and determination. Here are the top 20 systems that made that rapid evolution possible.
MITS Altair 8800
There once was a time that you could buy a top-of-the-line computer for $395. The only catch was that you had to build it yourself. Although the Altair 8800 wasn’t actually the first personal computer (Scelbi Computer Consulting’s 8008-based Scelbi-8H kit probably took that honor in 1973), it grabbed attention. MITS sold 2000 of them in 1975--more than any single computer before it.
Based on Intel’s 8-bit 8080 processor, the Altair 8800 kit included 256 bytes of memory (upgradable, of course) and a toggle-switch-and-LED front panel. For amenities such as keyboards, video terminals, and storage devices, you had to go to one of the companies that sprang up to support the Altair with expansion cards. In 1975, MITS offered 4- and 8-KB Altair versions of BASIC, the first product developed by Bill Gates’ and Paul Allen’s new company, Microsoft.
If the personal computer hobbyist movement was simmering, 1975 saw it come to a boil with the introduction of the Altair 8800.
Apple II
Those of you who think of the IBM PC as the quintessential business computer may be in for a surprise: The Apple II (together with VisiCalc) was what really made people look at personal computers as business tools, not just toys.
The Apple II debuted at the first West Coast Computer Faire in San Francisco in 1977. With built-in keyboard, graphics display, eight readily accessible exp ansion slots, and BASIC built into ROM, the Apple II was actually easy to use. Some of its innovations, like built-in high-resolution color graphics and a high-level language with graphics commands, are still extraordinary features in desktop machines.
With a 6502 CPU, 16 KB of RAM, a 16-KB ROM, a cassette interface that never really worked well (most Apple IIs ended up with the floppy drive that was announced in 1978), and color graphics, the Apple II sold for $1298.
Commodore PET
Also introduced at the first West Coast Computer Faire, Commodore’s PET (Personal Electronic Transactor) started a long line of inexpensive personal computers that brought computers to the masses. (The VIC-20 that followed was the first computer to sell 1 million units, and the Commodore 64 after that was the first to offer a whopping 64 KB of memory.)
The keyboard and small monochrome display both fit in the one-piece unit. Like the Apple II, the PET ran on MOS Te chnology’s 6502. Its $795 price, key to the PET’s popularity, supplied only 4 KB of RAM but included a built-in cassette tape drive for data storage and an 8-KB version of Microsoft BASIC in its 14-KB ROM.
Radio Shack TRS-80
Remember the Trash 80? Sold at local Radio Shack stores in your choice of color (Mercedes Silver), the TRS-80 was the first ready-to-go computer to use Zilog’s Z80 processor.
The base unit was essentially a thick keyboard with 4 KB of RAM and 4 KB of ROM (which included BASIC). An optional expansion box that connected by ribbon cable allowed for memory expansion. A Pink Pearl eraser was standard equipment to keep those ribbon cable connections clean.
Much of the first software for this system was distributed on audiocassettes played in from Radio Shack cassette recorders.
Osborne 1 Portable
By the end of the 1970s, garage start-ups were passe. Fortunately there were other entrepreneurial possibilities. Take Adam Osb Osborne 1 Portable , boasted a low price of $1795.
More important, Osborne established the practice of bundling software--in spades. The Osborne 1 came with nearly $1500 worth of programs: WordStar, SuperCalc, BASIC, and a slew of CP/M utilities.
Business was looking good until Osborne preannounced its next version while sitting on a warehouse full of Osborne 1s. Oops. Reorganization under Chapter 11 followed soon thereafter.
Xerox Star
This is the system that launched a thousand innovations in 1981. The work of some of the best people at Xerox PARC (Palo Alto Research Center) went into it. Several of these--the mouse and a desktop GUI with icons--showed up two years later in Apple’s Lisa and Macintosh computers.
The Star wasn’t what you’d call a commercial success, however. The main problem seemed to be how much it cost. I t would be nice to believe that someone shifted a decimal point somewhere: The pricing started at $50,000.
IBM PC
Irony of ironies that someone at mainframe-centric IBM recognized the business potential in personal computers. The result was the 1981 landmark announcement of the IBM PC . Thanks to an open architecture, IBM’s clout, and Lotus 1-2-3 (announced one year later), the PC and its progeny made business micros legitimate and transformed the personal computer world.
The PC used Intel’s 16-bit 8088, and for $3000, it came with 64 KB of RAM and a 5-1/4-inch floppy drive. The printer adapter and monochrome monitor were extras, as was the color graphics adapter.
Compaq Portable
Compaq’s Portable almost single-handedly created the PC clone market. Although that was about all you could do with it single-handedly--it weighed a ton. Columbia Data Products just preceded Compaq that year with the first true IB M PC clone but didn’t survive. It was Compaq’s quickly gained reputation for engineering and quality, and its essentially 100 percent IBM compatibility (reverse-engineered, of course), that legitimized the clone market. But was it really designed on a napkin?
Radio Shack TRS-80 Model 100
Years before PC-compatible subnotebook computers, Radio Shack came out with a book-size portable with a combination of features, battery life, weight, and price that is still unbeatable. (Of course, the Z80-based Model 100 didn’t have to run Windows.)
The $800 Model 100 had only an 8-row by 40-column reflective LCD (large at the time) but supplied ROM-based applications (including text editor, communications program, and BASIC interpreter), a built-in modem, I/O ports, nonvolatile RAM, and a great keyboard. Weighing under 4 pounds, and with a battery life measured in weeks (on four AA batteries), the Model 100 quickly became the first popular laptop, especially among journalists.
With its battery-backed RAM, the Model 100 was always in standby mode, ready to take notes, write a report, or go on-line. NEC’s PC 8201 was essentially the Kyocera-manufactured system.
Apple Macintosh
Whether you saw it as a seductive invitation to personal computing or a cop-out to wimps who were afraid of a command line, Apple’s Macintosh and its GUI generated even more excitement than the IBM PC. Apple’s R&D people were inspired by critical ideas from Xerox PARC (and practiced on Apple’s Lisa) but added many of their own ideas to create a polished product that changed the way people use computers.
The original Macintosh used Motorola’s 16-bit 68000 microprocessor. At $2495, the system offered a built-in high-resolution monochrome display, the Mac OS, and a single-button mouse. With only 128 KB of RAM, the Mac was underpowered at first. But Apple included some key applications that made the Macintosh immediately useful. (It was MacPaint that fin ally showed people what a mouse is good for.)
IBM AT
George Orwell didn’t foresee the AT in 1984. Maybe it was because Big Blue, not Big Brother, was playing its cards close to its chest. The IBM AT set new standards for performance and storage capacity. Intel’s blazingly fast 286 CPU running at 6 MHz and a 16-bit bus structure gave the AT several times the performance of previous IBM systems. Hard drive capacity doubled from 10 MB to 20 MB (41 MB if you installed two drives--just don’t ask how they did the math), and the cost per megabyte dropped dramatically.
New 16-bit expansion slots meant new (and faster) expansion cards but maintained downward compatibility with old 8-bit cards. These hardware changes and new high-density 1.2-MB floppy drives meant a new version of PC-DOS (the dreaded 3.0).
The price for an AT with 512 KB of RAM, a serial/parallel adapter, a high-density floppy drive, and a 20-MB hard drive was well over $5000--but much le ss than what the pundits expected.
Commodore Amiga 1000
The Amiga introduced the world to multimedia. Although it cost only $1200, the 68000-based Amiga 1000 did graphics, sound, and video well enough that many broadcast professionals adopted it for special effects. Its sophisticated multimedia hardware design was complex for a personal computer, as was its multitasking, windowing OS.
Compaq Deskpro 386
While IBM was busy developing (would "wasting time on" be a better phrase?) proprietary Micro Channel PS/2 systems, clone vendors ALR and Compaq wrested away control of the x86 architecture and introduced the first 386-based systems, the Access 386 and the Deskpro 386. Both systems maintained backward compatibility with the 286-based AT.
Compaq’s Deskpro 386 had a further performance innovation in its Flex bus architecture. Compaq split the x86 external bus into two separate buses: a high-speed local bus to support memory chips fast enough for the 16-MHz 386, and a slower I/O bus that supported existing expansion cards.
Apple Macintosh II
When you first looked at the Macintosh II , you may have said, "But it looks just like a PC." You’d have been right. Apple decided it was wiser to give users a case they could open so they could upgrade it themselves. The monitor in this 68020-powered machine was a separate unit that typically sat on top of the CPU case.
Next Nextstation
Unix had never been this easy to use, and only now, 10 years later, are we getting back to that level. Unfortunately, Steve Jobs’ cube never developed the software base it needed for long-term survival. Nonetheless, it served as an inspiration for future workstations.
Priced at less than $10,000, the elegant Nextstation came with a 25-MHz 68030 CPU, a 68882 FPU, 8 MB of RAM, and the first commercial magneto-optical drive (256-MB capacity). It also had a built-in DSP (digital signal processor). Th e programming language was object-oriented C, and the OS was a version of Unix, sugarcoated with a consistent GUI that rivaled Apple’s.
NEC UltraLite
NEC’s UltraLite is the portable that put subnotebook into the lexicon. Like Radio Shack’s TRS-80 Model 100, the UltraLite was a 4-pounder ahead of its time. Unlike the Model 100, it was expensive (starting price, $2999), but it could run MS-DOS. (The burden of running Windows wasn’t yet thrust upon its shoulders.)
Fans liked the 4.4-pound UltraLite for its trim size and portability, but it really needed one of today’s tiny hard drives. It used battery-backed DRAM (1 MB, expandable to 2 MB) for storage, with ROM-based Traveling Software’s LapLink to move stored data to a desktop PC.
Foreshadowing PCMCIA, the UltraLite had a socket that accepted credit-card-size ROM cards holding popular applications like WordPerfect or Lotus 1-2-3, or a battery-backed 256-KB RAM card.
Sun SparcStation 1
It wasn’t the first RISC workstation, nor even the first Sun system to use Sun’s new SPARC chip. But the SparcStation 1 set a new standard for price/performance, churning out 12.5 MIPS at a starting price of only $8995--about what you might spend for a fully configured Macintosh. Sun sold lots of systems and made the words SparcStation and workstation synonymous in many people’s minds.
The SparcStation 1 also introduced S-Bus, Sun’s proprietary 32-bit synchronous bus, which ran at the 20-MHz speed as the CPU.
IBM RS/6000
Sometimes, when IBM decides to do something, it does it right. (Other times...Well, remember the PC jr.?) The RS/6000 allowed IBM to enter the workstation market. The RS/6000’s RISC processor chip set (RIOS) racked up speed records and introduced many to the term superscalar. But its price was more than competitive. IBM pushed third-party software support, and as a result, many desktop publishing, CAD, and scientific applications po rted to the RS/6000, running under AIX, IBM’s Unix.
A shrunken version of the multichip RS/6000 architecture serves as the basis for the single-chip PowerPC, the non-x86-compatible processor with the best chance of competing with Intel.
Apple Power Macintosh
Not many companies have made the transition from CISC to RISC this well. The Power Macintosh represents Apple’s well-planned and successful leap to bridge two disparate hardware platforms. Older Macs run Motorola’s 680x0 CISC line, which is running out of steam; the Power Macs run the PowerPC RISC chip. The new Macs run existing 680x0-based applications yet provide PowerPC performance, a combination that sold over a million systems in a year.
IBM ThinkPad 701C
It’s not often anymore that a new computer inspires gee-whiz sentiment, but IBM’s Butterfly subnotebook does, with its marvelous expanding keyboard. The 701C’s two-part keyboard solves the last major piece in the puzzle of building a usable subnotebook: how to provide comfortable touch-typing. (OK, so the floppy drive is still external.)
With a full-size keyboard and a 10.4-inch screen, the 4.5-pound 701C compares favorably with full-size notebooks. Battery life is good, too.
Five Peripherals the PC Revolution Couldn’t Do Without
1) SHUGART 5-1/4-INCH FLOPPY DRIVEBefore PC hard drives were available, the floppy drive was the "mass" storage medium of choice. It killed paper tapes and audiocassettes.2) EPSON MX-80Fast and inexpensive, and it could also do graphics (with a later upgrade). What good is a spreadsheet chart if you can’t print it out? The competing daisy wheel’s advantage was typewriter text clarity.3) SEAGATE 5-1/4-INCH 5-MB WINCHESTER HARD DRIVENow this was mass storage that could fit in a PC--once the price came down. Alan Shugart was involved here, too.4) HAYES SMARTMODEM 300The modem that lau nched the industry-standard AT command set.5) HEWLETT-PACKARD LASERJETGraphics, speed, and sharp text for less than $2000, thanks to Canon’s 300-dpi laser engine. Using the engine, Apple came out with its LaserWriter shortly thereafter.
Apple’s 128k Mac
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"Anybody who could write a good application on the 128k Mac deserves a medal."--Bill Gates
It May Not Fly, But It Sure Took Off
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The story goes that the chairman of IBM looked at the original PC and said that it would never fly--that mainframes would dominate forever. Tell me again why people were buying stock in this company.
Osborne’s Barely-There Monitor
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Hello? Technical support? I think I misplaced the monitor for my Osborne portable. It does have a monitor, doesn’t it? Oh, that’s the monitor.
Clutter Could Be Apple III
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The Apple II gave a good name to cluttered garages all across the country. After all, you could always say that under that mess lay the components for the next great computer.
Sun’s SPARCStation Radiant in ’89
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Come on baby, light my fire. It wasn’t too hard to do with Sun’s SPARCStation 1 back in 1989. It was fast. It was cheap. The engineers who loved them looked no further for a very long time.
Compaq’s Portable...Just
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Compaq gave new meaning to the word portable with this 20-pound behemoth.
The Lightweight TRS-80 100
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A 4-pound bundle of joy: The TRS-80 100.
An Overblown Calculator
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Pet peeve? Someone took a desktop calculator and fed it steroids for a year to see what happens.
AT Architecture Lives On
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Eleven years later: Still living with the AT archi tecture.
Most Important Chips
All the chips on this list, obscure as some are, had a significant influence on the evolution of personal computing. So what does it take to make a computer today? Mostly, it seems, acronyms: a CPU, some RAM, a handful of EPROMs, a DSP, and a PCI bus.
Intel 1103
In 1970, Intel created the 1103--the first generally available DRAM chip. By 1972, it was the best-selling semiconductor memory chip in the world. Today, you would need more than 65,000 of them to put 8 MB of memory into a PC.
Intel 1702
In another brilliant stroke of naming, Intel created this, the first EPROM, in 1971. When you say "firmware," smile and think of the 1702.
Intel 4004
In 1971, Busicom, a Japanese company, wanted a chip for a new calculator. With incredible o verkill, Intel built the world’s first general-purpose microprocessor. Then it bought back the rights for $60,000.
The 4-bit 4004 ran at 108 kHz and contained 2300 transistors. Its speed is estimated at 0.06 MIPS. By comparison, Intel’s latest microprocessor, the P6 , runs at 133 MHz, contains 5.5 million transistors, and executes 300 MIPS.
Intel 8080
If you drive, your life probably depends on this chip. Introduced in April 1974, the 8080 was first widely used as a traffic-light controller. It found its way a year later into the world’s first personal computer: the MITS Altair.
MOS Technology 6502
What do a Nintendo set and a BMW have in common? The 6502. At $25 (compared with $375 for a comparable Motorola part), the 6502 was such a steal that a talented but cash-poor whiz kid from Silicon Valley, Steve Wozniak, chose it for his new personal computer, the Apple I.
Zilog Z80
Remember Tandy’s TRS-80 Model I? Remember CP/M? They were both built on the Z80.
Intel 8086 and 8088
Enter the King. In June 1978, the 8086 debuted. Today it stands for the world’s most popular microprocessor standard: the x86 architecture. A year later, Intel introduced a slight variation, the 8088, that could use 8-bit components, enabling the manufacture of inexpensive systems. For that reason, IBM chose the 8088 over the 8086 for the original IBM PC, even though the 8088 was slower.
Intel 386DX
The 386 heralded the beginning of a new age--the age of multitasking. Introduced in October 1985, the 386 was the first "modern" x86 processor that was capable of running today’s multitasking OSes, GUIs, and 32-bit software.
The 386 introduced an enhanced microarchitecture while maintaining full backward compatibility with earlier x86 processors. This was accomplished with two memory-addressing modes: real mode, which mi rrored the way memory is addressed by the older x86s, and a new protected mode that took full advantage of the 386’s 32-bit enhancements.
Intel Pentium
The Pentium swept through the PC industry faster than any of Intel’s previous chips. Although Intel’s 486DX (April 1989) integrated an FPU and was much faster than the 386, it was the Pentium that introduced the next leap forward in the x86 microarchitecture: superscalar pipelines. Skeptics said a CISC architecture couldn’t do it. The Pentium proved otherwise.
AMD 386DX
Let the price wars begin. When Intel’s original 16-MHz 386 was introduced in 1985, it cost $299; more than five years later, it was still commanding the relatively high price of $171, and the 33-MHz version fetched $214. AMD’s 386DX/40 appeared in March 1991 at $281, but within a year its price plunged 50 percent to $140. Street prices of PCs, which follow chip prices, fell by as much as $1000. The market for Windows-capable PCs expand ed by 33 percent.
Motorola 68000
More than any other, this is the microprocessor that helped establish the GUI. In 1983, four years after its introduction, it appeared in Apple’s Lisa, a unique computer but a commercial flop that nevertheless paved the way for the Macintosh in 1984.
Mips R2000
The R2000, introduced in 1986, was a 32-bit CPU with 110,000 transistors. It powered the first generation of RISC workstations and servers. The original version, clocked at 8 MHz, executed about 5 MIPS and had a separate FPU.
Sun Microsystems SPARC
In July 1987, Sun announced an open RISC architecture. The idea was to encourage multiple sourcing and lively competition that would spur performance and spread the SPARC standard far and wide. Eight years later, SPARC workstations and servers dominate their markets.
IBM/Motorola PowerPC 601
Although few doubted the power of the Po werPC architecture, many thought the politics of the IBM/Motorola/Apple relationship was going to be unmanageable.
In less than two years, it has spawned the world’s most popular RISC platform: the Power Macintosh.
Chips & Technologies AT Chip Set
IBM is not known for its approach to open systems. So, while it was actively resisting the cloning of its PC architecture, C&T was introducing its AT Chip Set. With only five chips, C&T duplicated the core logic of about 100 chips in IBM’s system. All a clone maker had to do was add a 286, a Phoenix BIOS ROM, and some memory to create a PC. Take that, Big Blue.
Amiga Agnes/Denise/Paula
It’s not a rock group: This was the advanced chip set that powered the world’s first multimedia computer: the Commodore Amiga 1000. In 1985, these three chips could do tricks that today’s PCs and Macs still can’t do--such as display multiple screens with independent pixel resolutions and bit depths on a single monitor.
Commodore SID
You can get remarkable results when you tell an engineer to do what he thinks is right. Take SID (Sound Interface Device), for example. In 1981, Bob Yannes was told to design a low-cost sound chip for the upcoming Commodore 64. He would end up creating an analog synthesizer chip that redefined the concept of sound in personal computers.
Yamaha OPL-2
Tweet. Beep, beep. Name that tune! The original IBM PC’s sound capabilities were practically nonexistent--a simple beeper that could produce a limited range of square-wave tones. Yamaha’s OPL-2 enabled vendors such as Ad Lib and Creative Labs to introduce plug-in sound boards with reasonable (but not great) sound. Today, nearly all PCs come with a sound board.
S3 911
Because PCs originally had character-oriented displays, screen performance drastically bogged down when running Microsoft Windows and graphical applications.
IBM’s 8514 chip and its spin-off s provided some improvement, but the market broke wide open in 1991 when S3 introduced the 911, which integrated GUI acceleration and VGA compatibility on a single chip.
Intel Mercury
The PCI (Peripheral Component Interconnect) bus is the most important enhancement to the PC architecture since the ISA bus, and Mercury was the first implementation. Today even Apple has adopted PCI to replace the NuBus.
A Calculator Microprocessor Run Amok
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The Intel 4004. It was supposed to be the brains of a calculator. Instead, it turned into a general-purpose microprocessor as powerful as ENIAC.
The Chip That Launched 68000 Macintoshes
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From Humble Origins
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This is Intel’s P6: All 5.5 million transistors, 133 MHz, and 300 MIPS of it. It’s roughly 5000 times as fast as the 4004. You’ve come a long way, x86.
It didn’t divide, but it conquered anyway
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