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Title: 1st%20chapter


1
1st chapter
  • Rashedul Hasan

2
1st Chapter.
  • What Computer is
  • -How does a Computer works
  • -Characteristics of Computer
  • -History of Computer
  • -Computer Generation
  • -Types of Computer

3
What computer is
  • The word Computer derives from Compute means
    To calculate
  • Calculating device that can perform arithmetic
    operation at high speed.
  • But to define a computer merely as a calculating
    device is to ignore over 80 of its Function.

4
Data processor
Input
process
output
process
Data
Information
Store
Retrieve
5
Data Information
  • Data Data is Raw material used as input to Data
    processing.
  • Information Information is processed data
    obtained as output of Data processing.

6
Data Processing
  • Processing in general terms, is a series of
    actions or operations that converts some input
    into useful output.
  • Hence, Data processing is a series of actions or
    operations that converts data into output.
  • Data processing transforms raw data into
    information.

7
Results Of Process -ing In Human acceptable for
m
Input data From External Source
Input Data In Internal form
Process -ed Data In Internal form
CPU Memory
output Devices
  • Input
  • Devices

8
What Computer is?
  • Four basic functions of computers include
  • Receive input
  • Process information
  • Produce output
  • Store information

9
Characteristics of Computer
  • Automatic An automatic machine works by itself
    without human intervention. Computers are
    automatic machine as once started on a job, it
    carry out the job normally without human
    assistance until it is finished. We only need to
    instruct computer using coded instruction.

10
  • Speed a computer is very fast device. It can
    perform in a few seconds, the amount of work that
    a human being can do in an entire year.
  • Computer can perform its tasks in a microsecond
    (10-6), nanosecond (10-9) and even in picoseconds
    (10-12),

11
  • Accuracy computers are very accurate. A computer
    can perform every calculation with the same
    accuracy over again and again.
  • However errors can occur in computer due to
    incorrect input data or unreliable programs.
  • Garbage in garbage out GIGO

12
  • Diligence Computer is free from monotony,
    tiredness and lack of concentration.
  • It do not call for strike, movement for pay rise
    and does not create any political instability.

13
  • Versatility It is the most important
    characteristics of computer. One moment it is
    preparing results of an examination, next moment
    it is busy preparing salary sheet, and in between
    it may play your favorite songs.
  • This is called multitasking ability.

14
  • Power of remembering People may forget many
    things over the time. But in case of computer, it
    can recall any amount of information stored in
    its memory.

15
  • No I.Q. Computer has no intelligence of its
    own. Its I.Q. is zero, at least until today. A
    computer cannot take its own decision. Only a
    user determines what tasks a computer will
    perform.

16
  • No feelings Computer has no emotion. Based on
    our feelings, taste, knowledge and experience we
    often make certain judgments in our day-to-day
    life whereas computer can not make such
    judgments.
  • what is good what is bad.

17
HOW DOES A COMPUTER WORK?
  • The computer accepts input. Computer input is
    whatever is entered or fed into a computer
    system. Input can be supplied by a person (such
    as by using a keyboard) or by another computer or
    device (such as a diskette or CD-ROM). Some
    examples of input include the words and symbols
    in a document, numbers for a calculation,
    instructions for completing a process, pictures,
    and so on.

18
HOW DOES A COMPUTER WORK?
  • ? The computer performs useful operations,
    manipulating the data in many ways. This
    manipulation is called processing. Examples of
    processing include performing calculations,
    sorting lists of words or numbers, modifying
    documents and pictures according to user
    instructions, and drawing graphs. A computer
    processes data in the CPU.

19
HOW DOES A COMPUTER WORK?
  • ? The computer stores data. A computer must store
    data so that it is available for processing. Most
    computers have more than one location for storing
    data (the hard drive or C\, and the floppy drive
    or A\). The place where the computer stores the
    data depends on how the data is being used. The
    computer puts the data in one place while it is
    waiting to be processed and another place when it
    is not needed for immediate processing. The
    storage of data in the computer is called online
    storage while the storage of data on computer
    tapes, diskettes or CD-ROMs is called offline
    storage.

20
HOW DOES A COMPUTER WORK?
  • ? The computer produces output. Computer output
    is information that has been produced by a
    computer. Some examples of computer output
    include reports, documents, music, graphs, and
    pictures. Output can be in several different
    formats, such as paper, diskette, or on screen.

21
Activity
  • Describe, in terms of input, processing and
    data, the production of a letter using a
    computer. What happens first? What happens last?

22
You could draw a simple flow chart that showed
the following
  • The input for the letter is received from
    keyboarding, scanning or copying data from a disk
  • The data are processed by the computer
  • The data are stored in a storage device, such as
    a floppy disk, hard disk or magnetic tape
  • The computer produces output in the form of a
    printed letter and an electronic version that may
    remain in the computer for future use or
    reference.

23
History of Computer
  • Pascal (1623-62) was the son of a tax collector
    and a mathematical genius. He designed the first
    mechanical calculator (Pascaline) based on gears.
    It performed addition and subtraction.
  • Leibnitz (1646-1716) was a German mathematician
    and built the first calculator to do
    multiplication and division. It was not reliable
    due to accuracy of contemporary parts.

24
History of Computer
  • Babbage (1792-1872) was a British inventor who
    designed an analytical engine incorporating the
    ideas of a memory and card input/output for data
    and instructions. Never actually built.
  • Babbage is largely remembered because of the work
    of Augusta Ada who was probably the first
    computer programmer.
  • Many people refer him as a father of computer.
  • Burroughs (1855-98) introduced the first
    commercially successful mechanical adding machine
    1,000,000 were sold by 1926.

25
History of Computer
  • Hollerith developed an electromechanical
    punched-card tabulator to tabulate the data for
    1890 U.S. census. Data was entered on punched
    cards and could be sorted according to the census
    requirements. The machine was powered by
    electricity. He formed the Tabulating Machine
    Company which became International Business
    Machines (IBM). IBM is currently the largest
    computer manufacturer, employing in excess of
    300,000 people.

26
History of Computer
  • Aiken (1900-73) a Harvard professor with the
    backing of IBM built the Harvard Mark I computer
    (51ft long) in 1944. It was based on relays
    (operate in milliseconds) as opposed to the use
    of gears. It required 3 seconds for a
    multiplication.

27
History of Computer
  • Eckert and Mauchly designed and built the ENIAC
    in 1946 for military computations. It used vacuum
    tubes (valves) which were completely electronic
    (operated in microseconds) as opposed to the
    relay which was electromechanical.
  • It weighed 30 tons, used 18000 valves, and
    required 140 kwatts of power. It was 1000 times
    faster than the Mark I multiplying in 3
    milliseconds. ENIAC was a decimal machine and
    could not be programmed without altering its
    setup manually.

28
History of Computer
  • Atanasoff had built a specialised computer in
    1941 and was visited by Mauchly before the
    construction of the ENIAC. He sued Mauchly in a
    case which was decided in his favour in 1974!

29
History of Computer
  • Von Neumann was a scientific genius and was a
    consultant on the ENIAC project. He formulated
    plans with Mauchly and Eckert for a new computer
    (EDVAC) which was to store programs as well as
    data.  
  • This is called the stored program concept and Von
    Neumann is credited with it. Almost all modern
    computers are based on this idea and are referred
    to as Von Neumann machines.  
  • He also concluded that the binary system was more
    suitable for computers since switches have only
    two values. He went on to design his own computer
    at Princeton which was a general purpose machine.

30
Examples of machines in the computer evolution
  • 14th C. - Abacus - an instrument for performing
    calculations by sliding counters along rods or in
    grooves
  • 17th C. - Slide rule - a manual device used for
    calculation that consists in its simple form of a
    ruler and a movable middle piece which are
    graduated with similar logarithmic scales
  • 1642 - Pascaline--a mechanical calculator built
    by Blaise Pascal
  • 1804 - Jacquard loom--a loom programmed with
    punched cards invented by Joseph Marie Jacquard
  • 1850 - Difference Engine , Analytical
    Engine--Charles Babbage and Ada Byron Babbage's
    description, in 1837, of the Analytical Engine, a
    mechanical digital computer anticipated virtually
    every aspect of present-day computers.

31
Examples of machines in the computer evolution
  • 1939 -1942 - Atanasoff Berry Computer - built at
    Iowa State by Prof. John V. Atanasoff and
    graduate student Clifford Berry. Represented
    several "firsts" in computing, including a binary
    system of of arithmetic, parallel processing,
    regenerative memory, separation of memory and
    computing functions, and more. Weighed 750 lbs.
    and had a memory storage of 3,000 bits (0.4K).
    Recorded numbers by scorching marks into cards as
    it worked through a problem.
  • 1946 - ENIAC--World's first electronic, large
    scale, general-purpose computer, built by Mauchly
    and Eckert, and activated at the University of
    Pennsylvania in 1946. ENIAC recreated on a modern
    computer chip. The ENIAC is a 30-ton machine,
    filled with 19,000 vacuum tubes, 6000 switches,
    and could add 5,000 numbers in a second, a
    remarkable accomplishment at the time. A
    reprogrammable machine, the ENIAC performed
    initial calculations for the H-bomb.
  • 1940s - Colossus - Alan Turing's vacuum tube
    computing machines broke Hitler's Enigma codes.

32
Examples of machines in the computer evolution
  • 1950s -1960s - UNIVAC - "punch card technology"
    The first commercially-successful computer,
    introduced in 1951 by Remington Rand. Over 40
    systems were sold. Its memory was made of
    mercury-filled acoustic delay lines that held
    1,000 12-digit numbers. It used magnetic tapes
    that stored 1MB of data at a density of 128 cpi.
    UNIVAC became synonymous with computer (for a
    while).

33
Evolution of Computing
No Computers
PCs introduced!
1960s
2001
1950
mid- 1970s
Very expensive computers for large companies.
Computer professionals ran the show.
Powerful PCs on every desktop. Explosion of
applications.
34
Computer Generation
  • Generation in computer talk is step in
    technology.
  • It is used to distinguish between various
    hardware technologies.
  • Totally 4 computer generations known till today.

35
COMPUTER GENERATIONS
  • 1. VACUUM TUBES 1946-1959

36
VACUUM TUBES
37
Tubes from a 1950s computer.
38
VACUUM TUBES
  • a vacuum tube is a device used to amplify,
    switch, otherwise modify, or create an electrical
    signal by controlling the movement of electrons
    in a low-pressure space.

39
Characteristics of 1st Generation computer
  • Too big in size.
  • Used vacuum tube.
  • Power consumption of these computers was very
    high.
  • Magnetic drums were developed to store
    information and tapes were also developed for
    secondary storage.
  • Power consumption of these computers was very
    high.
  • Limited commercial use. Mainly used for
    scientific computations.
  • Commercial production was difficult and costly.

40
COMPUTER GENERATIONS
  • 1. VACUUM TUBES 1946-1959
  • 2. TRANSISTORS 1957-1963

41
Transistors
42
Transistors
43
TRANSISTORS
  • a transistor is a semiconductor device commonly
    used to amplify or switch electronic signals.
  • The transistor is the fundamental building block
    of modern electronic devices.

44
Comparison with vacuum tubesAdvantages
  • Small size and minimal weight, allowing the
    development of miniaturized electronic devices.
  • Highly automated manufacturing processes,
    resulting in low per-unit cost.
  • Lower possible operating voltages, making
    transistors suitable for small, battery-powered
    applications.
  • No warm-up period for cathode heaters required
    after power application.
  • greater energy efficiency.
  • Higher reliable.
  • Extremely long life. Some transistorized devices
    produced more than 30 years ago are still in
    service.

45
Characteristics of 2nd Generation computer
  • Faster, smaller and more reliable.
  • Smaller in size than first generation computer
    and were more reliable and less prone to hardware
    failure.
  • They were more than ten times faster than the
    first generation computer.
  • Consumed almost one-tenth the power consumed by a
    tube.
  • Were less expensive.
  • Commercial production was still difficult and
    costly.
  • Another major feature of the second generation
    was the use of high-level programming languages
    such as Fortran and Cobol. These revolutionised
    the development of software for computers.

46
COMPUTER GENERATIONS
  • 1. VACUUM TUBES 1946-1959
  • 2. TRANSISTORS 1957-1963
  • 3. INTEGRATED CIRCUITS 1964-1979

47
INTEGRATED CIRCUITS
48
INTEGRATED CIRCUITS
  • an integrated circuit (also known as IC,
    microcircuit, microchip, silicon chip, or chip)
    is a miniaturized electronic circuit (consisting
    mainly of semiconductor devices) that has been
    manufactured in the surface of a thin plate of
    semiconductor material.

49
Generation of I.C.
  • The first integrated circuits contained only a
    few transistors. Called "Small-Scale Integration"
    (SSI), they used circuits containing transistors
    numbering in the tens.
  • The next generation in the development of
    integrated circuits, taken in the late 1960s,
    introduced devices which contained hundreds of
    transistors on each chip, called "Medium-Scale
    Integration" (MSI).

50
  • They were more powerful then 2nd generation
    computer. They were capable of performing 1
    million instruction per second.
  • They were smaller then 2nd generation computer
    requiring smaller place.
  • They consumed less power dissipated less heat.
  • Was suitable for commercial uses.
  • They were easier to upgrade.

51
COMPUTER GENERATIONS
  • 1. VACUUM TUBES 1946-1959
  • 2. TRANSISTORS 1957-1963
  • 3. INTEGRATED CIRCUITS 1964-1979
  • 4. VERY LARGE-SCALE INTEGRATED (VLSI) CIRCUITS
    1980- PRESENT

52
Very Large-Scale Integration
  • The final step in the development process,
    starting in the 1980s and continuing through the
    present, was "Very Large-Scale Integration"
    (VLSI). This could be said to start with hundreds
    of thousands of transistors in the early 1980s,
    and continues beyond several billion transistors
    as of 2007.

53
COMPUTER GENERATIONS
  • General purpose machine. Suitable for scientific
    commercial uses.
  • Cheaper and very powerful.
  • Much smaller and handy. (such as Laptop)
  • Consume less power and less prone to hardware
    failure than 3rd generation computers.
  • More reliable.
  • Faster and larger storage.
  • More user friendly interface with multi media
    features.
  • Graphical user interface enables new user to
    quickly learn how to use computer.
  • Easier to produce commercially.
  • Secondary storage has also evolved at fantastic
    rates with storage devices holding gigabytes
    (1000Mb 1 Gb) of data.

54
In short
55
Types of Computer
  • SUPERCOMPUTER
  • MAINFRAME
  • MINICOMPUTER
  • MICROCOMPUTER
  • LAPTOPS SMALLER

56
SUPERCOMPUTERTERAFLOP TRILLION
CALCULATIONS/SECOND
  • An extremely fast computer that can perform
    hundreds of millions of instructions per second.
  • Supercomputers are very expensive and are
    employed for specialized applications that
    require immense amounts of mathematical
    calculations. For example, weather forecasting
    requires a supercomputer. Other uses of
    supercomputers include fluid dynamic
    calculations, nuclear energy research, and
    petroleum exploration.

57
SUPERCOMPUTER
  • E.g.- CRAY Research- CRAY-1 CRAY-2,
  • Fujitsu (VP2000),
  • Hitachi (S820),
  • NEC (SX20),
  • PARAM 10000 by C-DAC.

58
General Use of Super Computer
  • Petroleum industry - to analyze volumes of
    seismic data which are gathered during oil
    seeking explorations to identify areas where
    there is possibility of getting petroleum
    products inside the earth
  • Aerospace industry - to simulate airflow around
    an aircraft at different speeds and altitude.
    This helps in producing an effective aerodynamic
    design for superior performance
  • Automobile industry to do crash simulation of
    the design of an automobile before it is released
    for manufacturing for better automobile design
  • Structural mechanics to solve complex
    structural engineering problems to ensure safety,
    reliability and cost effectiveness. Eg. Designer
    of a large bridge has to ensure that the bridge
    must be proper in various atmospheric conditions
    and pressures from wind, velocity etc and under
    load conditions. ?Meteorological centers use
    super computers for weather forecasting
  • Biomedical research atomic nuclear and plasma
    analysis to study the structure of viruses such
    as that causing AIDS
  • Other Use For weapons research and development,
    sending rockets to space etc

59
SUPERCOMPUTER
  • Teraflop Trillion calculations/second
  • Highly sophisticated
  • CPU speed 100 MIPS, Equivalent to 4000 computers
  • Complex computations
  • Fastest CPUS
  • Large simulations High precision
  • State-of-the-art components
  • Expensive

60
MAINFRAME
MIPS Millions of Instructions per second
  • A powerful multi-user computer capable of
    supporting many hundreds or thousands of users
    simultaneously.
  • mainframes are just below supercomputers.
  • The chief difference between a supercomputer and
    a mainframe is that a supercomputer channels all
    its power into executing a few programs as fast
    as possible, whereas a mainframe uses its power
    to execute many programs concurrently.
  • E.g.- IBM 3000 series, Burroughs B7900, Univac
    1180, DEC

61
MAINFRAME
62
MAINFRAME
63
  • Mainframe computers are large-sized, powerful
    multi-user computers that can support concurrent
    programs. That means, they can perform different
    actions or processes at the same time.
    Mainframe computers can be used by as many as
    hundreds or thousands of users at the same time.
    Large organizations may use a mainframe computer
    to execute large-scale processes such as
    processing the organizations payroll.

64
General Use of Mainframe Computer
  • Used to process large amount of data at very
    high speed such as in the case of Banks/
    Insurance Companies/ Hospitals/ Railway etc.
    which need online processing of large number of
    transactions and requires massive data storage
    and processing capabilities
  • Used as controlling nodes in WANs (Wide Area
    Networks)
  • Used to mange large centralized databases

65
MAINFRAME
  • MIPS millions of instructions per second
  • Largest enterprise computer
  • Able to process large amount of data at very high
    speed
  • Supports multi-user facility
  • Supports many I/O and auxiliary storage devices
  • 5o megabytes to over one gigabyte ram
  • Commercial, scientific, military applications
  • Massive data
  • Complicated computations

66
MINICOMPUTER
  • A multi-user computer capable of supporting from
    10 to hundreds of users simultaneously.
  • E.g.- Digital Equipments PDP 11/45 and VAX 11)
  • Middle-range
  • 10 megabytes to over one gigabyte ram
  • Universities, factories, labs
  • Used as front-end processor for mainframe. Can
    also communicate with main frames
  • Perform better than micros
  • Designed to support more than one user at a time
  • Posses large storage capacities and operates at
    higher speed

67
  • Mini-computers are mid-sized multi-processing
    computers. Again, they can perform several
    actions at the same time and can support from 4
    to 200 users simultaneously.
  • In recent years the distinction between
    mini-computers and small mainframes has become
    blurred. Often the distinction depends upon how
    the manufacturer wants to market its machines.
    Organizations may use a mini-computer for such
    tasks as managing the information in a small
    financial system or maintaining a small database
    of information about registrations or
    applications.

68
MICROCOMPUTER
  • A small, single-user computer based on a
    microprocessor. In addition to the
    microprocessor, a personal computer has a
    keyboard for entering data, a monitor for
    displaying information, and a storage device for
    saving data.
  • E.g.- IBM PC, PS/2 and Apple Macintosh
  • Microcomputer is generally used in the field of
    desktop publishing, accounting, statistical
    analysis, graphic designing, investment analysis,
    project management, teaching, entertainment etc

69
MICROCOMPUTER
  • Desktop or portable
  • They are designed to be used by only one person
    at a time
  • A microcomputer uses a microprocessor as its
    central processing unit. Microcomputers are tiny
    computers that can vary in size from a single
    chip to the size of a desktop model
  • Personal or business computers
  • Affordable
  • Many available components
  • Can be networked

70
  • Personal computers (PCs), also called
    microcomputers, are the most popular type of
    computer in use today. The PC is a small-sized,
    relatively inexpensive computer designed for an
    individual user. Today, the world of PCs is
    basically divided between IBM-compatible and
    Macintosh-compatible machines, named after the
    two computer manufacturers. Computers may be
    called desktop computers, which stay on the
    desk, or laptop computers, which are
    lightweight and portable. Organizations and
    individuals use PCs for a wide range of tasks,
    including word processing, accounting, desktop
    publishing, preparation and delivery of
    presentations, organization of spreadsheets and
    database management. Entry-level PCs are much
    more powerful than a few years ago, and today
    there is little distinction between PCs and
    workstations.

71
LAPTOPS SMALLER
  • PERSONAL COMPUTERS (PC) The name PC was given by
    the IBM for its microcomputers. PCs are used for
    word processing, spreadsheet calculations,
    database management etc.
  • LAPTOP (OR NOTEBOOK) Briefcase type package,
    very portable, can be inexpensive, can connect to
    other computers or networks
  • HAND-HELD (OR PALMTOP) Sub-miniature, wireless
    computer. Growing in sophistication and
    connectivity

72
Activity
  • If you have computer in your home find out the
    type or types. Are they mainframe computers,
    mini-computers, workstations or personal
    computers? What processes or actions are the
    computers used for? Write a brief description of
    the types of computers in place and their main
    uses. If you have more than one type of computer,
    find out why? What different tasks are the
    different computers intended to do?
  • If you have not any computer in your home, try to
    contact a colleague or friend who has a computer
    and ask him or her what type he or she has and
    what primary functions it is used for.
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