- •I. What is a computer?
- •II. Glimpses of history development of the transistor
- •The transistor and the computer. The computer's miniaturization
- •Planar technology
- •Integrated microcircuits come in
- •Microelectronics makes rapid progress
- •Birth of the microprocessor
- •Speedier semiconductor chips
- •III. The computer principles, structure and operation binary system
- •Logic circuits
- •Microelectronic memories
- •Using the computer
- •Data structures
- •Input. Process. Store, output
- •Output — video and printing devices
- •Video Terminals
- •IV. The computer's software programming a computer
- •Programming languages
- •Program development
- •Input Requirements
- •Table 5. Program Containing an Error
- •VI. Microcomputers in industry. Robotics machine tools5
- •Process control
- •Inspection and measurement
- •Robotics
- •The robot's nervous system
- •Robots in industry
- •VI. Educational applications of microelectronics computers on wheels
- •The computer teaches painting
- •A talking abc-book
- •VII. Computers all around us
- •Viewdata6
- •Integrated work station3
- •Multiple-fare meter2
- •Shade for the eyes. Music for the ears
- •Computer in a wristwatch
- •Talking watch
- •The doll talks
- •Pocket-size lie detector
- •Electronic watchman
- •Shock treatment2 for thieves
- •Passport for the electronic age
- •Illustrated copying instructions
- •Plain-speaking home robot
- •Touchy calculator
- •Optical discs: thanks for the memory
- •VIII. Computers at their best data base management systems'
- •Computer languages
- •The computer acquires intelligence
- •5 Whose syntax and structure lend themselves to interactive use — синтаксис и
- •Translation by computer
- •Enter the intelligent computer
- •Computers with intelligence
- •"Aesculapius"2 diagnoses the case
- •A smarter way to fly
- •Computer-controlled irrigation
Birth of the microprocessor
Since 1960 the complexity of the integrated circuits, i. e. the number of electronic elements on one chip, continued to double
' audio-amplifier — звуковой усилитель i at any instant of time -- в любой момент
3 mode of operation— принцип действия
4 numerical display— цифровое табло "' hardwired logic—логика с фиксированным монтажом; “жесткая”, “зашитая”
л оги ка " printed-circuit board — печатная плата
plug-in wire--съемный (сменный) провод
every year. Today we haven't yet seen any significant deviation from this exponential law. Nor are there any signs that the process is slowing down. The technology is still far from the fundamental limits imposed by the laws of physics: further miniaturization |is less likely to be limited by the taws of physics than by the laws of economics.'
The culmination of all these advancements was the microprocessor, which has become virtually synonymous with microelectronics, but should not be confused with it.
The microprocessor emerged in consequence of the progress of the microcalculators.
As we know, the electronic calculator in all but the latest versions uses hardwired logic. The arithmetic functions, or the operating program instructions, are embedded in the chips while the application program is in the user's head — his instructions yield the desired calculations2
M. E. Hoff, a young Intel Company engineer, envisaged a different way of employing the new electronic capabilities of the calculator- In 1969 he found himself in charge of a project that Intel took on for Busicom, a Japanese calculator company. Busicom wanted Intel to produce calculator chips of Japanese design. The logic circuits were spread around eleven chips and the complexity of the design would have taxed4 Intel capabilities — it was then a small company. Hoff saw a way to improve on the Japanese design by making a bold technological leap. The fact is Intel had pioneered in the development of semiconductor memory chips to be used in large computers. In the intricate innards of a memory chip, Hoff knew, it was possible to store a program to run a minuscule computing circuit.5
In his preliminary design, Hoff condensed the layout onto three chips. He put the computer's "brain", its central processing unit, on a single chip of silicon. That was possible because the semiconductor industry had developed a means of inscribing verv complex circuits on tiny surfaces. A master drawing,6 usually 500 times as large as the actual chip, is reduced photographically to microminiature size. The photo images are then transferred to the chip by the technique similar to photoengravmg.
Hoff's Central Processing Unit (CPU) on a chip became known as the microprocessor. The CPU comprised a logic unit, an arithme-
: is less tikely to be limited by the laws of physics than by the laws of economics -
по-ппл.имому, будет ограничена скорее законами экономики, чгм физик”
2 yield the desired calculations — обеспечивают необходимые расчеты
3 he found himself in charge of — it его ведении оказался
4 would have taxed -- потребовала бы максимального напряжения
й to run a minuscule computing circuit---для запуска крошечной счетной схемы
11 master drawing- фотооригипал (печатного монтажа)
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tic unit and a control unit. To the microprocessor Huff attached two memory chips, one to move data in and out of the CPU and one to provide the program to drive the CPU. Hoff now had in hand a rudimentary general-purpose computer' (microcomputer) that could not only run a complex calculator, but also control, for example, an elevator or a set of traffic lights, or a washing-machine, or a multifunction digital watch, and perform a great many other tasks, depending on its program only.
So the microprocessor is an integrated circuit which has the properties and fulfils the role of a complete central processing unit of a computer. This means that the circuit does not just react in a fixed, pre-programmed way2 to an input signal to produce an output signal- The main feature of the microprocessor is that its response and its logic can be altered- In other words, the microprocessor can be programmed in different ways rather than react in one pre-programmed .way only.
For logic and systems designers the appearance of the microprocessor brought with it a dramatic change in the way they employed electronics. They could now replace all those rigid hardwired logic systems with microcomputers because they could store program sequences in the labyrinthine circuits of the memory chips instead of using individual logic chips and discrete components to implement the program. Engineers could thus substitute program code words for hardware parts3
It took about three years before the first devices reached the market but in the meantime about a hundred different microprocessors had become available. As with at] microelectronic products, the capabilities of microprocessors advanced rapidly and the sophistication of circuits increased day by day.
After other Intel engineers who took over the detailed design work got through with it,4 Hoff's invention contained 2250 microminiaturized transistors on a chip slightly less than one-sixth of an inch long and one-eighth of an inch wide, and each of those microscopic transistors was roughly equal to an ENIAC vacuum tube. Intel labelled the microprocessor chip 4004 -and the whole microcomputer MCS-4 (microcomputer systern-4). Despite its small size, the 4004 just about matched ENIAC computational power. It also matched the capability of an IBM machine of the early 1960s whose centra] processing unit (CPU) took up the space of an office desk.
' general-purpose computer — универсальная ЭВМ '•' in a fixed, pre-programmed way -- жестко устяжжж-ииым. чшрограммироп.ж.-
НЫ.М Обр;!;”1М
hardware parts - лгтали оборудования 4 got through with it — закончили ее
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