The world computer comes from a latin word which means to count

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Поддержка инструмент перевода: Клингонский (pIqaD), Определить язык, азербайджанский, албанский, амхарский, английский, арабский, армянский, африкаанс, баскский, белорусский, бенгальский, бирманский, болгарский, боснийский, валлийский, венгерский, вьетнамский, гавайский, галисийский, греческий, грузинский, гуджарати, датский, зулу, иврит, игбо, идиш, индонезийский, ирландский, исландский, испанский, итальянский, йоруба, казахский, каннада, каталанский, киргизский, китайский, китайский традиционный, корейский, корсиканский, креольский (Гаити), курманджи, кхмерский, кхоса, лаосский, латинский, латышский, литовский, люксембургский, македонский, малагасийский, малайский, малаялам, мальтийский, маори, маратхи, монгольский, немецкий, непальский, нидерландский, норвежский, ория, панджаби, персидский, польский, португальский, пушту, руанда, румынский, русский, самоанский, себуанский, сербский, сесото, сингальский, синдхи, словацкий, словенский, сомалийский, суахили, суданский, таджикский, тайский, тамильский, татарский, телугу, турецкий, туркменский, узбекский, уйгурский, украинский, урду, филиппинский, финский, французский, фризский, хауса, хинди, хмонг, хорватский, чева, чешский, шведский, шона, шотландский (гэльский), эсперанто, эстонский, яванский, японский, Язык перевода.

To many people, the computer is a superhuman robot. Indeed, it can perform lightingfast calculations and can perform billions of operations in a second. But the computer is not superhuman for itcan accomplish none of these things by itself. Every computer

now in existence must be told what to do: it must have a set of instructions. The writing of these instructions is called programming. Programming is done by a man.

Для многих людей компьютер — сверхчеловеческий робот. В самом деле, он может выполнять сверхскоростные вычисления и может выполнять миллиарды операций в секунду. Но компьютер не сверхчеловек, так как он не может выполнить ни одну из этих вещей сам по себе. Каждому компьютеру, существующему в настоящее время нужно сказать, что делать: он должна иметь набор инструкций. Написания этих инструкций называется программированием. Программирование осуществляется с помощью человека.

Surely, there are similarities with human brain, but there exists one important difference. Despite all its accomplishments, the electronic brain must be programmed by a human brain.

Конечно, есть сходство с человеческим мозгом, но существует одно важное отличие. Несмотря на все свои достижения, электронный мозг должен быть запрограммирован человеческим мозгом.

Although accepted for different purposes, computers virtually do not differ in

structure. Regardless of their size or purpose most computer systems consist at least of three elements: the input-output ports, the memory hierarchy and the central processing unit.

Хотя принятые в различных целях, компьютеры практически не отличаются по своей структуре. Независимо от их размера или цели большинство компьютерных систем состоят как минимум из трех элементов: портов вводавывода, иерархии памяти и центрального процессора.

The input-output ports are known to be paths whereby information (instructions and data) is fed into the computer or taken out of it.

Порты ввода-вывода, как известно, это каналы, по которым информация (инструкции и данные) подается в компьютер или выводится из него.

There are several types of memory. Memory is essential to the computer’s operation. Items of information can be written to, stored in, retrieved from it on

demand by the central processing unit, or erased32 to make room for other information.

Есть несколько типов оперативной памяти. Память имеет важное значение для работы компьютера. Информация может записываться, храниться, извлекаться из компьютера по требованию центрального процессора, или удалятся, чтобы освободить место для другой информации.

The central processing unit, or CPU, controls the operation of the entire system

by issuing commands to other parts of the system and by acting on the responses. When required, itreads information from the memory, interprets instructions, performs operations on the data according to the instructions, writes the results back into the memory, and moves information between memory levels or through the input-output ports.

Центральный процессор, или просто процессор, управляет работой всей системы путем выдачи команд на другие части системы и, откликается на ответы. При необходимости, он считывает информацию из памяти, интерпретирует инструкции, выполняет операции над данными в соответствии с инструкциями, записывает результаты обратно в память, и передает информацию между уровнями памяти или с помощью портов ввода-вывода.

Advances in microelectronic components led to the development of smaller computers. In 1971 Intel. Corp. delivered the first microprocessor, the 4004. The central processing unit of a computer was put onto a single silicon chip less than 1/4 in square. When a central processing unit (CPU) of a computer is implemented in a single, or very small number of integrated circuits, we call it amicroprocessor. When a

computer incorporates a microprocessor as a major component, we call it a microcomputer. When the entire computer, including CPU, memory and input-output capability, is incorporated into a single 1C, we call the latter a one-chip microcompute.

Достижения в области микроэлектронных компонентов привели к развитию меньших компьютеров. В 1971 году Корпорация Intel поставила первый микропроцессор, 4004. Центральный процессор компьютера был поставлен на одном кристалле кремния менее 1/4 квадрата. Когда центральный процессор (CPU) компьютера реализован в виде одной микросхемы, или в виде очень небольшого количества интегральных схем, мы называем это микропроцессором. Когда компьютер включает в себя микропроцессор в качестве основного компонента, мы называем это микрокомпьютер. Когда весь компьютер, включая процессор, память и порты ввода-вывода, включен в одиночный 1С, мы называем это однокристальным микрокомпьютером.

The first design was followed by many others. The progress toward smaller computers is certain to continue: gradually there appear nano- computers and pico-computers. These computers are more flexible. Modern computers are virtually symbiotic.

Первый проект породил многие другие. Прогресс в сторону меньших компьютеров, несомненно, будет продолжаться: постепенно появляются нанокомпьютеров и пико-компьютеры. Эти компьютеры более гибкие. Современные компьютеры практически симбиотические.

Advances in microelectronics give rise to advances in computers. Computers today are providing an expanding range of services.

Достижения в области микроэлектроники привели к достижениям в области вычислительной техники. Компьютеры сегодня предоставляют расширение спектра услуг.

Computers are classified by size and capability as microcomputers, mainframes and supercomputers, depending on the size of their main memories and on their processing speed.

Компьютеры классифицируются по размеру и возможностям, на микрокомпьютеры, большие компьютеры (ЭВМ) и суперкомпьютеры, в зависимости от размера их основной памяти и от скорости обработки данных.

Most microcomputers are mostly used by individuals.

Большинство микрокомпьютеров в основном используются частными лицами.

Mainframes are used by large corporations, government agencies and other large institutions.

ЭВМ используются крупными корпорациями, правительственными агентствами и другими крупными учреждениями.

Supercomputers are the largest and fastest of all computers. They have memories and processing speeds that may be measured in several picoseconds (trillions of a second). The boundaries separating the categories change frequently as computer technology advances.

Суперкомпьютеры крупные и самые быстрые из всех компьютеров. У них есть память и скорость обработки, которые могут быть измерены в несколько пикосекунд (триллионы секунд). Границы, разделяющие категории часто меняются в зависимости от достижений техники.

I. The word «computer» comes from a Latin word which means to count.¹ A computer is reallу a very special kind of counting machine.

Initially,² the computer was designed as a tool to manipulate numbers and thus solve arithmetic problems. Although designed originally³ for arithmetic purposes at present it is applicable for a great variety of tasks.

Nowadays computers are considered to be complicated⁴ machines for doing arithmetic and logic. The computer may be stated to have become an important and powerful tool for collect­ing, recording,⁵ analysing, and distributing⁶ tremendous masses of information.

Viewed⁷ in the contemporary⁸ scene and historical per­spective the computer simulates man. Indeed,⁹ two important and highly visible characteristics of man are his intelligence and his ability to perform in and control his environment.¹⁰

Significantly, man’s attempts to understand the phenomena of intelligence, control and power has led to simulations of his brain, of himself and of organizational and group structures in which he most often finds himself. In the last 30 years man has made exten­sive use of the computer for these simulations.

Surely, there are similarities with human brain, but there ex­ists one very important difference. Despite¹¹ all its ac­complishments,¹² the so-called electronic brain must be pro­grammed by a human brain.

As already stated, originally computers were used only for doing calculations.

Today it would be difficult to find any task that calls for¹³ the processing of large amounts¹⁴ of information that is not per­formed by a computer. In science computers digest and analyse masses of measurements, such as the sequential¹⁵ positions and velocities of a spacecraft and solve extraordinary long and complex mathematical problems, such as the trajectory of the spacecraft. In commerce¹⁶ they record and process inventories, purchases (по­купка), bills, payrolls (платежная ведомость), bank deposits and the like and keep track of ongoing business transactions.¹⁷ In industry they monitor¹⁸ and control manufacturing processes. In government they keep statistics and analyse economic infor­mation.

A computer system can perform millions of operations a sec­ond. In the mid-1950’s the average¹⁹ speed of main-memory²⁰ was about 10 ms, in the mid-1960’s 1 ms, in the mid-1970’s a tenth to a hundredth of a microsecond and in the mid-1980’s it largely increased.

The computer’s role is influenced not only by its speed but also by its memory-size. A large memory makes it easier to work with large programs, including data (compare linear programming or regression analysis requiring large matrices).

The increase in main memory capacity has been spectacular²¹ too: mid-1950’s 100 thousand bits, mid-1960’s 1 to 10 million, mid-1970’s nearly 1 billion bits. Secondary storage²² has been greatly expanded by the use of discs. Primary and secondary storage have been integrated by the virtual memory technique.

Although accepted for different purposes computers virtually do not differ in structure.

Any computer is, architecturally, like any other computer. Regardless²³ of their size or purpose most computer systems consist of three basic elements: the input-output ports,²⁴ the memory hierarchy and the central processing unit. The input-out­put ports are paths whereby²⁵ information (instructions and data) is fed²⁶ into the computer or taken out of it by such means as punch cards,²⁷ magnetic tages and terminals. The memory hierarchy stores the instructions (the program) and the data in the system so that they can be retrieved²⁸ quickly on deinjpd by the central processing unit. The central processing unit controls the operation of the entire²⁹ system by issuing³⁰ commands to other parts of the system and by acting on the responses. When required it reads³¹ information from mememory, interprets³² instructions, performs operations on the data according to the instructions, writes the results back into the memory and moves information between memory levels or through the input-output ports. The operations it performs on the data can be either arithmetic or logical.

As stated above any computer is, architecturally, like any other computer in the early days of computers. However, there are differences. They are the following: An early processor used to be made of thousands of vacuum tubes. Reliability was measured in mere hours between failures, and the cooling plant was often larger than the computer itself. Then, the transistor was invented. The number of them was enormous in each mainframe. Besides, in computers of the 1950’s, the transistors, diodes, resistors, ca­pacitors and other components were mounted³³ on printed-circuit (PC) cards. A typical 5-in. card contained a dozen transistors and a hundred other parts. A card might have contained a single flip-flop³⁴ and a thousand cards were required to build each computer.

In the early 1960’s semiconductors makers created a wholly new technology, a whole flip-flop could be integrated. Several of integrated circuits (ICs) could be mounted on a single printed card.³⁵ Soon, improved fabrication processes enabled even more complex circuit to be created in a single IC. The new technology was called medium-scale integration (MSI), and the older tech­nology was labelled³⁶ small-scale integration (SSI). The progress towards smaller computers continued.

If used for computers discrete transistors were too costly and unreliable, they were too large and too slow.

In the 1960’s advances in microelectronic components led to the development of the minicomputer, followed more recently by an even smaller microcomputer. Both have filled a need for small but relatively flexible³⁷ processing systems able to execute³⁸ comparatively simple computing functions at lower cost.

In 1971, Intel Corp. delivered the first microprocessor, the 4004. All the logic to implement³⁹ the CPU, the central processing unit, of a tiny computer was put onto a single silicon chip less than 1/4-in square. That design was soon followed by many others. The progress toward smaller computers is likely to continue: there is already talk of nano-computers and pico-computers.

When the central processing unit (CPU) of a computer is im­plemented in a single or very small number of integrated circuits, we call it a microprocessor. When a computer incorporates⁴⁰ a microprocessor as its major component, the resulting configura­tion is called a microcomputer. When the entire computer, in­cluding CPU, memory and input-output capability, is incorporated into a single IC, we also call that configuration a microcomputer. To distinguish⁴¹ between the two microprocessor types, we call the latter a one-chip microcomputer.

Modern computers and microelectronic devices have in­teracted so closely in their evolution that they can be regarded as virtually symbiotic. Microelectronics and data processing are linked.⁴²

Today the hardware in data-processing machines is built out of microelectronic devices. Advances in microelectronic devices give rise to advances in data-processing machinery.

As previously pointed computers today are providing an ex­panding range of services to rapidly growing pool (количество) of users. Such facilities⁴³ could make our lives easier, and indeed they already enhance the productivity. Yet a bottleneck (труд­ность) remains which hinders⁴⁴ the wider availability of such systems; this bottleneck is the man-machine communication barrier.

Simply put, todays systems are not very good at com­municating with their users. They often fail⁴⁵, to understand what their users want them to do and then are unable to explain the nature of the misunderstanding to the user. Communication with the machines is sometimes time-consuming.⁴⁶ What are the causes of this communication barrier?

One of the most important causes of the man-machine com­munication barrier is that an interactive computer system typically responds only to commands phrased with total accuracy in a highly restricted⁴⁷ artificial⁴⁸ language designed specifically for that system. If a user fails to use this language or makes a mistake, however small, an error⁴⁹ message⁵⁰ is the response he can ex­pect.

II. Several developments have helped to reduce programming effort. High-level languages like FORTRAN, ALGOL, PL-1, and COBOL have replaced assembler languages to a great extent. There is a trend⁵¹ towards languages with a free format and more error checking.⁵² Thus programming itself takes less time since fewer errors are made and residual⁵³ errors are detected and corrected more rapidly. ADA seems destined⁵⁴ to become the dominant programming language of 1980’s. The term «ADA» comes from the name of Byron’s daughter Ada, Lady Lovelace. She was the first programmer in the world.

These high-level languages, however, require more com­pilation and running time, and more memory space.

Currently,⁵⁵ almost all man-machine interaction takes place through typed input and output. Superficially,⁵⁶ at least, it is this mode, that human communication needs.

However, this type of man-machine communication is rapidly becoming outmoded⁵⁷ by a generation of powerful personal computers. These machines are intended⁵⁸ for dedicated use by a single individual and feature an integral high-resolution, bit-map, graphics display with a pointing device, as well as a conventional keyboard. This allows the computers to provide multiple in­dependent output channels. Besides extra communication chan­nels, such machines provide for different communication modali­ties: a graphics screen⁵⁹ can display line drawings or images⁶⁰ and produce attention-commanding effects such as highlighting (вы­свечивать) or flashing the background⁶¹ of certain areas of the screen.

The multiple communication channels and modalities allow for more effective interaction.

Recent Computer technology advances are the following: Voice annotations Facsimile images, High-drawn sketches, Animated sequences. The potential advantages of multimedia communications technology are too great to ignore.

Many scientists are conducting a research on man-machine communication. The work is ongoing. Of particular interest are information systems that model complex real-world events.

Active information systems are database processing tools in­tended to represent and manipulate data descriptions of large real-world systems that have a complex dynamic behaviour.⁶²

It is apparent⁶³ that if the language of recipient and sender differs, the data of the message cannot be used. Problems in un­derstanding the content must be resolved by cooperation between the sender and the recipient.

In automated information systems the computers must re­ceive and at the same time interpret and act on the data. In infor­mation systems, to be more explicit, the fields of computers and communications are merging.⁶⁴

In this case data reliability is a significant design factor. More and more data are stored in machines without paper or manual backup.⁶⁵ That data must be accurate, protected, and available.

Besides computers and information systems are becoming more distributed. At the same time the integration and co­ordination of the individual information systems and computers in an organization are becoming more of necessity. This introduces new requirements, design parameters, and tradeoffs.⁶⁶

These considerations affect system issues ranging from the ar­chitecture of specific computers to the architecture of overall in­formation systems.

To sum up, computers have certain disadvantages. We have not given them those common-sense skills⁶⁷ of interaction and communication that people find so natural and effortless. Nevertheless computers are fast enough to permit man to control mechanisms having rates of response exceeding his own reaction time.

The computer has made it possible to mechanize much of the information interchange and processing that constitute⁶⁸ the nervous system of our society.

The versatility,⁶⁹ and convenience⁷⁰ of the microprocessor has altered the entire architecture of modern computer systems. No longer is the processing of information carried out only in the computer’s central processing unit. Today there is a trend toward distributing more processing capability throughout a computer system, with various areas having smafi local processors for han­dling operations in those areas.

There are a number of advantages to distributed processing. First, since many elements of the computer can be working on different portions of the same task, the work may be done faster. Second, if one element in the network malfunctions, its work­load⁷¹ can be shifted to another element or shared among several elements, sothat the entire work is relatively immune to failure. Third, the network can be small enough to be contained within a single laboratory or building, or it can be spread out over a wide area.

A major obstacle⁷² to designing an effective distributed-processing system is the difficulty involved in writing the system’s software, which must enable the various elements of the network to operate and interact efficiently.

The method of processing data as well as available peripheral devices define computer generations.⁷³ We are now operating third and fourth generation computers and looking ahead to the fifth. An advantage of the fifth generation will be the ability of people without knowledge of programming to use computer ter­minals. Remote⁷⁴ processing will be common too.