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Generations of Computers

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1 Generations of Computers
Any sufficiently advanced technology is indistinguishable from magic. Arthur C. Clarke

2 Charles Babbage 1822 - The Difference Engine
Babbage invented a mechanical "difference engine" for the calculation of arithmetical functions and set out plans for an "analytical engine" whose operation would have included logarithmic and trigonometric functions as well. 1991 Reproduction of the Difference Engine Babbage invented a mechanical "difference engine" for the calculation of arithmetical functions and set out plans for an "analytical engine" whose operation would have included logarithmic and trigonometric functions as well.

3 Mark Mark I The Mark 1 is seen as the first full-sized digital computer. It weighed 5 tons, had 500 miles of wiring, was used only for numeric calculations, and took three seconds to carry out one multiplication computation. The first large scale, automatic, general purpose, electromechanical calculator was the Harvard Mark I (AKA IBM Automatic Sequence Control Calculator [ASCC]) conceived by Howard Aiken in the late 1930's and implemented by IBM. The machine, sponsored by the US Navy, was intended to compute the elements of mathematical and navigation tables -- the same purpose as intended by Babbage for the Difference Engine. Aiken dedicated his early reports to Babbage, having been made aware of the piece of the Difference Engine at Harvard in The ASCC was not a stored program machine but instead was driven by a paper tape containing the instructions. The Mark 1 is seen as the first full-sized digital computer. It weighed 5 tons, had 500 miles of wiring, was used only for numeric calculations, and took three seconds to carry out one multiplication.

4 1st Generation of Computers
Vacuum Tubes

5 ENIAC 1945 The ENIAC was 1,000 times faster than the Mark 1. introduced the vacuum tube technology. No longer were mechanical moving parts used to perform operations. The massive ENIAC, which weighed 30 tons and filled an entire room, used some 18,000 vacuum tubes, 70,000 resistors, and 10,000 capacitors. In December 1945 it solved its first problem, calculations for the hydrogen bomb. After its official unveiling in 1946, it was used to prepare artillery-shell trajectory tables and perform other military and scientific calculations. [Reference ID: ]

6 ENIAC could add, subtract, multiply, divide, and extract square roots
ENIAC could add, subtract, multiply, divide, and extract square roots. ENIAC stored a maximum of twenty 10-digit decimal numbers. Its accumulators combined the functions of an adding machine and storage unit. It contained 20,000 vacuum tubes.

7 1947 IBM SSEC The IBM Selective Sequence Electronic Calculator
IBM's Selective Sequence Electronic Calculator (SSEC), built at IBM's Endicott facility under the direction of Columbia Professor Wallace Eckert and his Watson Scientific Computing Laboratory staff in , shown here after it was moved to the new IBM Headquarters Building at 590 Madison Avenue in Manhattan [4], where it occupied the periphery of a room 60 feet long and 30 feet wide [42] (Herb Grosch [59] estimates the dimensions of its "U" shape at feet, 180 feet in all, about half a football field!) 1947

8 UNIVAC 1951 The UNIVAC I (the name stood for Universal Automatic Computer) was delivered to the Census Bureau in It weighed some 16,000 pounds, used 5,000 vacuum tubes, and could perform about 1,000 calculations per second. It was the first American commercial computer, as well as the first computer designed for business use. (Business computers like the UNIVAC processed data more slowly than the IAS-type machines, but were designed for fast input and output.) The first few sales were to government agencies, the A.C. Nielsen Company, and the Prudential Insurance Company. The first UNIVAC for business applications was installed at the General Electric Appliance Division, to do payroll, in By 1957 Remington-Rand (which had purchased the Eckert-Mauchly Computer Corporation in 1950) had sold forty-six machines. Later modificaitons of the UNIVAC were the first computers to use transistors instead of vacuum tubes. A Later modification of the UNIVAC was the first computer to make use of transistors instead of vacuum tubes.

9 IBM 702 The 702, which operated on the decimal system, incorporated a central arithmetical and logical unit capable of performing more than 10 million operations in an hour. The memory unit of the 702 contained a bank of 84 cathode ray tubes, on the faces of which thousands of decimal digits could be stored through the presence or absence of charged spots. Reels of magnetic tape fed data to the machine and recorded answers at the rate of 15,000 letters or numbers a second. One 2,400-foot reel of tape held information from 25,000 fully punched cards. 1955

10 From Vacuum Tubes to Transistors
Text p The second Generation of Computers 2nd Generation of Computers

11 IBM 1401 Model T of computers

12 3rd Generation of Computers 1964-1975
Integrated Circuits

13 Digital PDP Programmed Data Processor
The PDP was the first commercial computer that came with a monitor

14 Circuitry encased in chips
Computers produce less heat and run many programs with a central program to coordinate the computer’s memory and components.

15 1969 1969: The US Department of Defense commissions Arpanet for research networking, and the first four nodes come operations al UCLA, UC Santa Barbara, SRI, and the University of Utah. Arpanet laid the foundation for the Internet. Here we have the first true computer network. Since it is all still fairly basic, it is worth considering the underlying principles have basically remained the same (even if they, mercifully, operate far faster and look much prettier). We start off with a passive terminal and an active host, a keyboard and a computer. They are linked together by a cable. By typing in commands recognised by a computer, you can use the programs stored in its computer, access its files (and modify them and print them out as desired). Most people can envisage this arrangement within a single building, or complex of buildings. In order to access another computer, at a completely different facility, we have first to reach it. This was usually done in these times over a (high speed) telephone line (or lines). Once you arrive at the new 'host' you have to convince it to treat you in the same way as someone behind a terminal within its own system. Hence the need of an interface message processor (IMP) and for the same IMP to be installed in both computers! Now you can access its files. Of course, order to preserve confidentiality, all computers differentiated between 'open' files and those that were password protected. If you wanted to transfer a file or program to your own computer, the host computer uses a program to break it down into 'packages' attaching to each the address and its original position. It then sends them to your 'home' computer where a mirror program reassembles the message in the original order. In future, you could then access them from your home base. When dealing with a 'simple' network like ARPANET it is difficult to see what the real advantage of this process was. But this would soon change...In 1973, work began on tcp-ip to make this process easier.

16 Moore’s Law Gordon Moore Cost of 1 MHz of Processing Power
1970 – $7, $ .17 Cost of 1 mb Storage 1970 – $ .17 Cost of sending 1 trillion bits $150, $ .12 Gordon Moore

17 1971 – The First Microprocessor
Intel 4004 dubbed “a computer on a chip” The Pioneer 10 spacecraft used the 4004 microprocessor. It was launched on March 2, 1972.

18 Pong

19 1973 - Large scale integration
10,000 components are placed on a 1cm2 chip While attending Harvard, Bill Gates and Paul Allen developed a version of the programming language BASIC for the first microcomputer, the MITS Altair. The 1975 Altair (kit) used large scale integration

20 4th Generation of Computers
Mid – 1970’s – Current Large-Scale Integration

21 1976 CRAY I

22 1977 – Apple II

23 Radio Shack TRS - 80 1977 – Tandy Commodore

24 Microsoft

25 1977 – Cellphones

26 1981 - IBM PC The first open architecture computer goes mainstream

27 1984 – Apple MacIntosh

28 1984 – CD ROM

29 1985- Intel 386

30 1985 – Windows 1.0

31 1989 – Intel 486 1.2 Million Transistors

32 1989 Tim Berners-Lee World Wide Web
URL HTML

33 1993 – Intel Pentium 3.5 million transistors

34 1994 Marc Andreeson Netscape

35 1995 – Windows 95

36 1995 – Amazon.com First large internet site for commerce

37 1996 – Windows CE

38 1997 – IBM’s “Big Blue” beat world chess champion Garry Kasparov in only 62 minutes.

39 1997 Intel Pentium II 233 MHz

40 1999 – Intel Pentium III 500 MHz

41 Pentium IV Today's microprocessors contain tens of millions of microscopic transistors.

42 Artificial Intelligence
Fifth Generation Voice Recognition Artificial Intelligence

43


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