Evolution Of Computer

Everything has their Evolution and develop from time to time like human , Mobile and even Computer in topic it time to understand the evolution of you computer that being used to read this article.

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The Mechanical Era (1623-1945) 

Trying to use machines to solve mathematical problems can be traced to the early 17th
century. Wilhelm Schickhard, Blaise Pascal, and Gottfried Leibnitz were among

mathematicians who designed and implemented calculators that were capable of addition,
subtraction, multiplication, and division included   The first multi-purpose or programmable
computing device was probably Charles Babbage's Difference Engine, which was begun in
1823 but never completed. In 1842, Babbage designed a more ambitious machine, called the
Analytical Engine but unfortunately it also was only partially completed.  Babbage, together
with Ada Lovelace recognized several important programming techniques, including
conditional branches, iterative loops and index variables.   Babbage designed the machine
which is arguably the first to be used in computational science. In 1933, George Scheutz  and
his son, Edvard began work on a smaller version of the difference engine and by 1853 they
had constructed a machine that could process 15-digit numbers and calculate fourth-order
differences.  The US Census Bureau was one of the first organizations to use the mechanical
computers which used punch-card equipment designed by Herman Hollerith to tabulate data
for the 1890 census. In 1911 Hollerith's company merged with a competitor to found the
corporation which in 1924 became International Business Machines (IBM).

First Generation Electronic Computers (1937-1953) 

These devices used electronic switches, in the form of vacuum tubes, instead of
electromechanical relays.  The earliest attempt to build an electronic computer was by J. V.
Atanasoff, a professor of physics and mathematics at Iowa State in 1937. Atanasoff set out to
build a machine that would help his graduate students solve systems of partial differential
equations. By 1941 he and graduate student Clifford Berry had succeeded in building a
machine that could solve 29 simultaneous equations with 29 unknowns. However, the
machine was not programmable, and was more of an electronic calculator.

A second early electronic machine was Colossus, designed by Alan Turing for the British
military in 1943.  The first general purpose programmable electronic computer was the
Electronic Numerical Integrator and Computer (ENIAC), built by J. Presper Eckert and John
V. Mauchly at the University of Pennsylvania. Research work began in 1943, funded by the
Army Ordinance Department, which needed a way to compute ballistics during World War
II. The machine was completed in 1945 and it was used extensively for calculations during
the design of the hydrogen bomb.  Eckert, Mauchly, and John von Neumann, a consultant to
the ENIAC project, began work on a new machine before ENIAC was finished. The main
contribution of EDVAC, their new project, was the notion of a stored program.  ENIAC was
controlled by a set of external switches and dials; to change the program required physically
altering the settings on these controls. EDVAC was able to run orders of magnitude faster
than ENIAC and by storing instructions in the same medium as data, designers could
concentrate on improving the internal structure of the machine without worrying about
matching it to the speed of an external control.  Eckert and Mauchly later designed what was
arguably the first commercially successful computer, the UNIVAC; in 1952.  Software
technology during this period was very primitive.

Second Generation (1954-1962) 

The second generation witnessed several important developments at all levels of computer
system design, ranging from the technology used to build the basic circuits to the
programming languages used to write scientific applications.  Electronic switches in this era
were based on discrete diode and transistor technology with a switching time of
approximately 0.3 microseconds. The first machines to be built with this technology include
TRADIC at Bell Laboratories in 1954 and TX-0 at MIT's Lincoln Laboratory.  Index
registers were designed for controlling loops and floating point units for calculations based
on real numbers.

A number of high level programming languages were introduced and these include
FORTRAN (1956), ALGOL (1958), and COBOL (1959). Important commercial machines of
this era include the IBM 704 and its successors, the 709 and 7094.  In the 1950s the first two
supercomputers were designed specifically for numeric processing in scientific applications.

Third Generation (1963-1972) 

Technology changes in this generation include the use of integrated circuits, or ICs
(semiconductor devices with several transistors built into one physical component),
semiconductor memories, microprogramming as a technique for efficiently designing
complex processors and the introduction of operating systems and time-sharing.  The first ICs
were based on small-scale integration (SSI) circuits, which had around 10 devices per circuit
(or ‘chip’), and evolved to the use of medium-scale integrated (MSI) circuits, which had up to
100 devices per chip. Multilayered printed circuits were developed and core memory was
replaced by faster, solid state memories.
In 1964, Seymour Cray developed the CDC 6600, which was the first architecture to use
functional parallelism. By using 10 separate functional units that could operate
simultaneously and 32 independent memory banks, the CDC 6600 was able to attain a
computation rate of one million floating point operations per second (Mflops).  Five years
later CDC released the 7600, also developed by Seymour Cray. The CDC 7600, with its
pipelined functional units, is considered to be the first vector processor and was capable of
executing at ten Mflops. The IBM 360/91, released during the same period, was roughly
twice as fast as the CDC 660.
Early in this third generation, Cambridge University and the University of London
cooperated in the development of CPL (Combined Programming Language, 1963). CPL was,
according to its authors, an attempt to capture only the important features of the complicated

and sophisticated ALGOL. However, like ALGOL, CPL was large with many features that
were hard to learn. In an attempt at further simplification, Martin Richards of Cambridge
developed a subset of CPL called BCPL (Basic Computer Programming Language, 1967). In
1970 Ken Thompson of Bell Labs developed yet another simplification of CPL called simply
B, in connection with an early implementation of the UNIX operating system. comment):

Fourth Generation (1972-1984) 

Large scale integration (LSI - 1000 devices per chip) and very large scale integration (VLSI -
100,000 devices per chip) were used in the construction of the fourth generation computers.
Whole processors could now fit onto a single chip, and for simple systems the entire
computer (processor, main memory, and I/O controllers) could fit on one chip. Gate delays
dropped to about 1ns per gate.  Core memories were replaced by semiconductor memories.
Large main memories like CRAY 2 began to replace the older high speed vector processors,
such as the CRAY 1, CRAY X-MP and CYBER  
In 1972, Dennis Ritchie developed the C language from the design of the CPL and
Thompson's B. Thompson and Ritchie then used C to write a version of UNIX for the DEC
PDP-11.   Other developments in software include very high level languages such as FP
(functional programming) and Prolog (programming in logic).
IBM worked with Microsoft during the 1980s to start what we can really call PC (Personal
Computer) life today.  IBM PC was introduced in October 1981 and it worked with the
operating system (software) called ‘Microsoft Disk Operating System (MS DOS) 1.0.
Development of MS DOS began in October 1980 when IBM began searching the market for
an operating system for the then proposed IBM PC and major contributors were Bill Gates,
Paul Allen and Tim Paterson.  In 1983, the Microsoft Windows was announced and this has
witnessed several improvements and revision over the last twenty years.  

 Fifth Generation (1984-1990) 

This generation brought about the introduction of machines with hundreds of processors that
could all be working on different parts of a single program. The scale of integration in
semiconductors continued at a great pace and by 1990 it was possible to build chips with a
million components - and semiconductor memories became standard on all computers.
Computer networks and single-user workstations also became popular.  
Parallel processing started in this generation.  The Sequent Balance 8000 connected up to 20
processors to a single shared memory module though each processor had its own local cache.
The machine was designed to compete with the DEC VAX-780 as a general purpose Unix
system, with each processor working on a different user's job. However Sequent provided a
library of subroutines that would allow programmers to write programs that would use more
than one processor, and the machine was widely used to explore parallel algorithms and
programming techniques.  The Intel iPSC-1, also known as ‘the hypercube’ connected each
processor to its own memory and used a network interface to connect processors. This
distributed memory architecture meant memory was no longer a problem and large systems
with more processors (as many as 128) could be built. Also introduced was a machine,
known as a data-parallel or SIMD where there were several thousand very simple processors
which work under the direction of a single control unit.  Both wide area network (WAN) and
local area network (LAN) technology developed rapidly.

Sixth Generation (1990 -  ) 

Most of the developments in computer systems since 1990 have not been fundamental
changes but have been gradual improvements over established systems.  This generation
brought about gains in parallel computing in both the hardware and in improved
understanding of how to develop algorithms to exploit parallel architectures.

 Workstation technology continued to improve, with processor designs now using a
combination of RISC, pipelining, and parallel processing.   Wide area networks, network
bandwidth and speed of operation and networking capabilities have kept developing
tremendously.  Personal computers (PCs) now operate with Gigabit per second processors,
multi-Gigabyte disks, hundreds of Mbytes of RAM, colour printers, high-resolution graphic
monitors, stereo sound cards and graphical user interfaces.  Thousands of software (operating
systems and application software) are existing today and Microsoft Inc. has been a major
contributor.  Microsoft is said to be one of the biggest companies ever, and its chairman –
Bill Gates has been rated as the richest man for several years.
Finally, this generation has brought about micro controller technology.  Micro controllers are
’embedded’ inside some other devices (often consumer products) so that they can control the
features or actions of the product.  They work as small computers inside devices and now
serve as essential components in most machines.

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