Radicalism was in the air in 1970. The Vietnam war wasn't gaining much support on college campuses. In the streets, the flower-power Hippies had been shoved aside by angry, politicized Yippies, who took to the protest barricades to hurl scorn—and a couple of rocks—at the Establishment. Nixon's White House wasn't having any of it, though, and battle lines were drawn here at home. The "enemies list" that resulted set the tone for a presidency that ended in defeat and disgrace in the Waterloo known as Watergate.
But radicalism wasn't confined to the streets. In the engineering labs of semiconductor manufacturers, radical ideas were taking shape. The design, and even the basic concept, of electronic systems had rushed headlong to a defining moment. In the pre-IC days, transistors were employed to build logical functions, taking the place of the vacuum tube and improving on many of its shortcomings. When transistors were combined on ICs, they represented a great step forward in miniaturization and flexibility.
The time was right for the next great step. What if circuitry could be made programmable? Why should we settle for circuits that could only do the single function they were designed to do? And what if we could put a whole lot more of the circuitry on a single silicon substrate?
Those concepts, realized in the microprocessor, are the fulcrum upon which almost all electronic advances since have rested. In 1971, a Japanese manufacturer named Busicom contracted Intel to produce the chips for its new programmable calculator. The team of Intel engineers convinced the company that its ideas were too cumbersome for the usual logic techniques. The team argued that the design was best realized as three ICs: a central processing unit (CPU), or "brain," and two memory chips. The result was the 4004 microprocessor, a 4-bit device whose descendents have invaded every aspect of human existence in the 30-odd years since.
Measuring one-eighth by one-sixteenth of an inch, the 4004 had all of 2300 transistors. At the close of the sixties, the term "large-scale integration," or LSI, had begun to be applied to the increasingly complex ICs flooding out of the semiconductor foundries. The 4004 was the clearest evocation yet of what LSI would ultimately come to mean. This fingertip-sized slab of silicon was as powerful as the 30-ton ENIAC computer built in 1946. And although they're not exactly computers on a chip, microprocessors perform many of the functions of the CPUs in the computers that came before them.
It's almost poetic justice that a calculator design was the microprocessor's first home. Calculators, digital watches, and other consumer devices were at the vanguard of electronic applications in the early seventies. The changes wrought by the explosion of IC technology into society reached in every direction, even into the engineering labs themselves. The calculators were the death of the engineers' beloved slide rules. The creators had to face their creations and, sometimes, they resisted them.
In society at large, technology wasn't always immediately accepted either. The 1970s can be thought of as the first decade in which consumer electronics applications carried as much clout, if not more, than military applications. A lot of adjustments came with the rapid dissemination of microprocessors into homes, businesses, and factories. Who hasn't struggled with programming a VCR? That minor inconvenience, which first appeared on the scene in mid-decade, was vexing enough. But technology was downright threatening to some. Could we really trust those computers to keep track of our bank accounts? Will we lose our jobs to computerization? Scariest of all, what if a computer goes haywire and starts a nuclear war? These questions, and others, were raised by an anxious society that remembered all too well the rogue computer HAL in Stanley Kubrick's 1968 film, 2001: A Space Odyssey.
Despite the anxiety that microprocessors may have provoked, there was no putting them back in the box. For one thing, their size and programmability lent them to applications that were simply impossible using discrete IC approaches. On the heels of the 4004, Intel quickly came up with the 8008, an 8-bit processor that further broadened the scope of applications for these machines. More powerful and flexible than the 4004, the 8008, while still a limited device, was the only 8-bit processor available until the improved 8080 appeared in 1974. By mid-decade, a slew of microprocessors had been developed. Sixteen-bit microprocessors made their debut before the decade ended.
Over the course of the decade, microprocessors and their cousins, microcontrollers, appeared in scores of appliances, including microwave ovens and washing machines. Video games such as Pong were among the popular applications, sparking a huge industry that has been not only a voracious consumer of microprocessors but also a cauldron of innovation for graphics and display technology to this day.
Microprocessors are powerful devices, but it was understood that they couldn't function without memory. By the late sixties, the concept of cache memory had been devised by IBM engineers and implemented using bipolar memories that were expensive and had small capacities. But in 1970, Intel rolled out a 1024-bit dynamic RAM that set the stage for later advances in memory devices. That same year, Intel produced the first 2-kbit UV EPROM, launching a memory technology that would survive for 20 years. With DRAMs and UV EPROMs on the scene along with the microprocessor, engineers had quite a bit to work with as they moved forward with computer development.
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