Introduction
A computer is a device
that can be instructed to carry out sequences of arithmetic or logical
operations automatically via computer programming. Modern computers have the
ability to follow generalized sets of operations, called programs. These
programs enable computers to perform an extremely wide range of tasks. Computers
are used as control systems for a wide variety of industrial and consumer
devices. This includes simple special purpose devices like microwave ovens and
remote controls, factory devices such as industrial robot sand computer-aided
design, and also general purpose devices like personal computers and mobile
devices such as smartphones.
Early computers were
only conceived as calculating devices. Since ancient times, simple manual
devices like the abacus aided people in doing calculations. Early in the
Industrial Revolution, some mechanical devices were built to automate long
tedious tasks, such as guiding patterns for looms. More sophisticated
electrical machines did specialized analog calculations in the early 20th
century. The first digital electronic calculating machines were developed
during World War II. The speed, power, and versatility of computers have been
increasing dramatically ever since then. Conventionally, a modern computer consists
of at least one processing element, typically a central processing unit(CPU),
and some form of memory. The processing element carries out arithmetic and
logical operations, and a sequencing and control unit can change the order of
operations in response to stored information. Peripheral devices include input
devices (keyboards, mice, joystick, etc.), output devices (monitor screens,
printers, etc.), and input/output devices that perform both functions (e.g.,
the 2000 s-era touchscreen). Peripheral devices allow information to be
retrieved from an external source and they enable the result of operations to
be saved and retrieved.
Pre-20th century
Devices have been used
to aid computation for thousands of years, mostly using one-to-one
correspondence with fingers. The earliest counting device was probably a form
of tally stick. Later record keeping aids throughout the Fertile Crescent
included calculi (clay spheres, cones, etc.) which represented counts of items,
probably livestock or grains, sealed in hollow unbaked clay containers. The use
of counting rods is one example. The abacus was initially used for arithmetic
tasks. The Roman abacus was developed from devices used in Babylonia as early
as 2400 BC. Since then, many other forms of reckoning boards or tables have
been invented. In a medieval European counting house, a checkered cloth would
be placed on a table, and markers moved around on it according to certain
rules, as an aid to calculating sums of money.
The Antikythera
mechanism is believed to be the earliest mechanical analog
"computer", according to Derek J. de Solla Price. It was designed to
calculate astronomical positions. It was discovered in 1901 in the Antikythera
wreck off the Greek island of Antikythera, between Kythera and Crete, and has
been dated to circa 100 BC. Devices of a level of complexity comparable to that
of the Antikythera mechanism would not reappear until a thousand years later. Many
mechanical aids to calculation and measurement were constructed for astronomical
and navigation use. The planisphere was a star chart invented by Abū Rayhān
al-Bīrūnī in the early 11th century. The astrolabe was invented in the
Hellenistic world in either the 1st or 2nd centuries BC and is often attributed
to Hipparchus. A combination of the planisphere and dioptra, the astrolabe was
effectively an analog computer capable of working out several different kinds
of problems in spherical astronomy. An astrolabe incorporating a mechanical
calendar computer and gear-wheels was invented by Abi Bakr of Isfahan, Persia
in 1235. Abū Rayhān al-Bīrūnī invented the first mechanical geared lunisolar
calendar astrolabe, an early fixed-wired knowledge processing machine with a
gear train and gear-wheels, circa 1000 AD.
The sector, a
calculating instrument used for solving problems in proportion, trigonometry,
multiplication and division, and for various functions, such as squares and
cube roots, was developed in the late 16th century and found application in
gunnery, surveying and navigation. The planimeter was a manual instrument to
calculate the area of a closed figure by tracing over it with a mechanical
linkage. The slide rule was invented around 1620–1630, shortly after the
publication of the concept of the logarithm. It is a hand-operated analog
computer for doing multiplication and division. As slide rule development
progressed, added scales provided reciprocals, squares and square roots, cubes
and cube roots, as well as transcendental functions such as logarithms and
exponentials, circular and hyperbolic trigonometry and other functions. Slide
rules with special scales are still used for quick performance of routine
calculations, such as the E6B circular slide rule used for time and distance
calculations on light aircraft.
In the 1770s, Pierre
Jaquet-Droz, a Swiss watchmaker, built a mechanical doll (automaton) that could
write holding a quill pen. By switching the number and order of its internal
wheels different letters, and hence different messages, could be produced. In
effect, it could be mechanically "programmed" to read instructions.
Along with two other complex machines, the doll is at the Musée d'Art et
d'Histoire of Neuchâtel, Switzerland, and still operates. The tide-predicting
machine invented by Sir William Thomson in 1872 was of great utility to
navigation in shallow waters. It used a system of pulleys and wires to
automatically calculate predicted tide levels for a set period at a particular
location. The differential analyser, a mechanical analog computer designed to
solve differential equations by integration, used wheel-and-disc mechanisms to
perform the integration. In 1876, Lord Kelvin had already discussed the
possible construction of such calculators, but he had been stymied by the
limited output torque of the ball-and-disk integrators.[16] In a differential
analyzer, the output of one integrator drove the input of the next integrator,
or a graphing output. The torque amplifier was the advance that allowed these
machines to work. Starting in the 1920s, Vannevar Bush and others developed
mechanical differential analyzers.
First computing device
A portion of Babbage's
Difference engine.
Charles Babbage, an English mechanical
engineer and polymath, originated the concept of a programmable computer.
Considered the "father of the computer", he conceptualized and
invented the first mechanical computer in the early 19th century. After working
on his revolutionary difference engine, designed to aid in navigational
calculations, in 1833 he realized that a much more general design, an
Analytical Engine, was possible. The input of programs and data was to be
provided to the machine via punched cards, a method being used at the time to
direct mechanical looms such as the Jacquard loom. For output, the machine
would have a printer, a curve plotter and a bell. The machine would also be
able to punch numbers onto cards to be read in later. The Engine incorporated
an arithmetic logic unit, control flow in the form of conditional branching and
loops, and integrated memory, making it the first design for a general-purpose
computer that could be described in modern terms as Turing-complete.
The machine was about
a century ahead of its time. All the parts for his machine had to be made by
hand – this was a major problem for a device with thousands of parts.
Eventually, the project was dissolved with the decision of the British
Government to cease funding. Babbage's failure to complete the analytical
engine can be chiefly attributed to difficulties not only of politics and
financing, but also to his desire to develop an increasingly sophisticated
computer and to move ahead faster than anyone else could follow. Nevertheless,
his son, Henry Babbage, completed a simplified version of the analytical
engine's computing unit (the mill) in 1888. He gave a successful demonstration
of its use in computing tables in 1906.
Analog computers
During the first half
of the 20th century, many scientific computing needs were met by increasingly
sophisticated analog computers, which used a direct mechanical or electrical
model of the problem as a basis for computation. However, these were not
programmable and generally lacked the versatility and accuracy of modern
digital computers. The first modern analog computer was a tide-predicting
machine, invented by Sir William Thomson in 1872. The differential analyser, a
mechanical analog computer designed to solve differential equations by
integration using wheel-and-disc mechanisms, was conceptualized in 1876 by
James Thomson, the brother of the more famous Lord Kelvin.
The art of mechanical
analog computing reached its zenith with the differential analyzer, built by H.
L. Hazen and Vannevar Bush at MIT starting in 1927. This built on the
mechanical integrators of James Thomson and the torque amplifiers invented by
H. W. Nieman. A dozen of these devices were built before their obsolescence
became obvious. By the 1950s, the success of digital electronic computers had
spelled the end for most analog computing machines, but analog computers
remained in use during the 1950s in some specialized applications such as
education (control systems) and aircraft (slide rule).
Digital computers
Electromechanical
By 1938, the United
States Navy had developed an electromechanical analog computer small enough to
use aboard a submarine. This was the Torpedo Data Computer, which used
trigonometry to solve the problem of firing a torpedo at a moving target.
During World War II similar devices were developed in other countries as well. Early digital computers were electromechanical; electric
switches drove mechanical relays to perform the calculation. These devices had
a low operating speed and were eventually superseded by much faster
all-electric computers, originally using vacuum tubes. The Z2, created by
German engineer Konrad Zuse in 1939, was one of the earliest examples of an
electromechanical relay computer.
In 1941, Zuse followed his earlier machine up
with the Z3, the world's first working electromechanical programmable, fully
automatic digital computer. The Z3 was built with 2000 relays, implementing a
22 bit word length that operated at a clock frequency of about 5–10 Hz.[24]
Program code was supplied on punched film while data could be stored in 64
words of memory or supplied from the keyboard. It was quite similar to modern
machines in some respects, pioneering numerous advances such as floating point
numbers. Rather than the harder-to-implement decimal system (used in Charles
Babbage's earlier design), using a binary system meant that Zuse's machines
were easier to build and potentially more reliable, given the technologies
available at that time. The Z3 was Turing complete.
Vacuum tubes and digital electronic circuits
Purely electronic
circuit elements soon replaced their mechanical and electromechanical
equivalents, at the same time that digital calculation replaced analog. The
engineer Tommy Flowers, working at the Post Office Research Station in London
in the 1930s, began to explore the possible use of electronics for the
telephone exchange. Experimental equipment that he built in 1934 went into
operation five years later, converting a portion of the telephone exchange
network into an electronic data processing system, using thousands of vacuum
tubes. In the US, John Vincent Atanasoff and Clifford E. Berry of Iowa State
University developed and tested the Atanasoff–Berry Computer (ABC) in 1942, the
first "automatic electronic digital computer". This design was also
all-electronic and used about 300 vacuum tubes, with capacitors fixed in a
mechanically rotating drum for memory. During World War II,
the British at Bletchley Park achieved a number of successes at breaking
encrypted German military communications. The German encryption machine,
Enigma, was first attacked with the help of the electro-mechanical bombes which
were often run by women. To crack the more sophisticated German Lorenz SZ 40/42
machine, used for high-level Army communications, Max Newman and his colleagues
commissioned Flowers to build the Colossus. He spent eleven months from early
February 1943 designing and building the first Colossus. After a functional
test in December 1943, Colossus was shipped to Bletchley Park, where it was
delivered on 18 January 1944 and attacked its first message on 5 February.
Colossus was the
world's first electronic digital programmable computer. It used a large number
of valves (vacuum tubes). It had paper-tape input and was capable of being
configured to perform a variety of boolean logical operations on its data, but
it was not Turing-complete. Nine Mk II Colossi were built (The Mk I was
converted to a Mk II making ten machines in total). Colossus Mark I contained
1,500 thermionic valves (tubes), but Mark II with 2,400 valves, was both 5
times faster and simpler to operate than Mark I, greatly speeding the decoding
process. ENIAC was the first electronic,
Turing-complete device, and performed ballistics trajectory calculations for
the United States Army. The U.S.-built ENIAC (Electronic Numerical Integrator
and Computer) was the first electronic programmable computer built in the US.
Although the ENIAC was similar to the Colossus, it was much faster, more
flexible, and it was Turing-complete. Like the Colossus, a "program"
on the ENIAC was defined by the states of its patch cables and switches, a far
cry from the stored program electronic machines that came later. Once a program
was written, it had to be mechanically set into the machine with manual
resetting of plugs and switches. The programmers of the ENIAC were six women,
often known collectively as the "ENIAC girls".
It combined the high
speed of electronics with the ability to be programmed for many complex
problems. It could add or subtract 5000 times a second, a thousand times faster
than any other machine. It also had modules to multiply, divide, and square
root. High speed memory was limited to 20 words (about 80 bytes). Built under
the direction of John Mauchly and J. Presper Eckert at the University of
Pennsylvania, ENIAC's development and construction lasted from 1943 to full
operation at the end of 1945. The machine was huge, weighing 30 tons, using 200
kilowatts of electric power and contained over 18,000 vacuum tubes, 1,500
relays, and hundreds of thousands of resistors, capacitors, and inductors.
Modern computers
Concept of modern computer
The principle of the
modern computer was proposed by Alan Turing in his seminal 1936 paper, On
Computable Numbers. Turing proposed a simple device that he called
"Universal Computing machine" and that is now known as a universal
Turing machine. He proved that such a machine is capable of computing anything
that is computable by executing instructions (program) stored on tape, allowing
the machine to be programmable. The fundamental concept of Turing's design is
the stored program, where all the instructions for computing are stored in
memory. Von Neumann acknowledged that the central concept of the modern computer
was due to this paper. Turing machines are to this day a central object of
study in theory of computation. Except for the limitations imposed by their
finite memory stores, modern computers are said to be Turing-complete, which is
to say, they have algorithm execution capability equivalent to a universal
Turing machine.
Stored programs
Three tall racks
containing electronic circuit boards
Early computing
machines had fixed programs. Changing its function required the re-wiring and
re-structuring of the machine. With the proposal of the stored-program computer
this changed. A stored-program computer includes by design an instruction set
and can store in memory a set of instructions (a program) that details the
computation. The theoretical basis for the stored-program computer was laid by
Alan Turing in his 1936 paper. In 1945, Turing joined the National Physical
Laboratory and began work on developing an electronic stored-program digital
computer. His 1945 report "Proposed Electronic Calculator" was the
first specification for such a device. John von Neumann at the University of
Pennsylvania also circulated his First Draft of a Report on the EDVAC in 1945.
The Manchester Baby
was the world's first stored-program computer. It was built at the Victoria
University of Manchester by Frederic C. Williams, Tom Kilburn and Geoff
Tootill, and ran its first program on 21 June 1948. It was designed as a
testbed for the Williams tube, the first random-access digital storage device.
Although the computer was considered "small and primitive" by the
standards of its time, it was the first working machine to contain all of the
elements essential to a modern electronic computer. As soon as the Baby had
demonstrated the feasibility of its design, a project was initiated at the
university to develop it into a more usable computer, the Manchester Mark 1.
Grace Hopper was the first person to develop a compiler for programming
language.
The Mark 1 in turn
quickly became the prototype for the Ferranti Mark 1, the world's first
commercially available general-purpose computer.[46] Built by Ferranti, it was
delivered to the University of Manchester in February 1951. At least seven of
these later machines were delivered between 1953 and 1957, one of them to Shell
labs in Amsterdam. In October 1947, the directors of British catering company
J. Lyons & Company decided to take an active role in promoting the
commercial development of computers. The LEO I computer became operational in
April 1951 and ran the world's first regular routine office computer job.
Transistors
A bipolar junction transistor
The bipolar transistor
was invented in 1947. From 1955 onwards transistors replaced vacuum tubes in
computer designs, giving rise to the "second generation" of
computers. Compared to vacuum tubes, transistors have many advantages: they are
smaller, and require less power than vacuum tubes, so give off less heat.
Silicon junction transistors were much more reliable than vacuum tubes and had
longer, indefinite, service life. Transistorized computers could contain tens
of thousands of binary logic circuits in a relatively compact space.
At the University of
Manchester, a team under the leadership of Tom Kilburn designed and built a
machine using the newly developed transistors instead of valves. Their first
transistorised computer and the first in the world, was operational by 1953,
and a second version was completed there in April 1955. However, the machine
did make use of valves to generate its 125 kHz clock waveforms and in the
circuitry to read and write on its magnetic drum memory, so it was not the
first completely transistorized computer. That distinction goes to the Harwell
CADET of 1955, built by the electronics division of the Atomic Energy Research
Establishment at Harwell.
Integrated circuits
The next great advance
in computing power came with the advent of the integrated circuit. The idea of
the integrated circuit was first conceived by a radar scientist working for the
Royal Radar Establishment of the Ministry of Defence, Geoffrey W.A. Dummer. Dummer
presented the first public description of an integrated circuit at the
Symposium on Progress in Quality Electronic Components in Washington, D.C. on 7
May 1952.
The first practical
ICs were invented by Jack Kilby at Texas Instruments and Robert Noyce at
Fairchild Semiconductor. Kilby recorded his initial ideas concerning the
integrated circuit in July 1958, successfully demonstrating the first working
integrated example on 12 September 1958. In his patent application of 6
February 1959, Kilby described his new device as "a body of semiconductor
material ... wherein all the components of the electronic circuit are
completely integrated". Noyce also came up with his own idea of an
integrated circuit half a year later than Kilby. His chip solved many practical
problems that Kilby's had not. Produced at Fairchild Semiconductor, it was made
of silicon, whereas Kilby's chip was made of germanium.
This new development
heralded an explosion in the commercial and personal use of computers and led
to the invention of the microprocessor. While the subject of exactly which
device was the first microprocessor is contentious, partly due to lack of
agreement on the exact definition of the term "microprocessor", it is
largely undisputed that the first single-chip microprocessor was the Intel
4004, designed and realized by Ted Hoff, Federico Faggin, and Stanley Mazor at
Intel.
Mobile computers
The first mobile
computers were heavy and ran from mains power. The 50lb IBM 5100 was an early
example. Later portables such as the Osborne 1 and Compaq Portable were
considerably lighter, but still needed to be plugged in. The first laptops,
such as the Grid Compass, removed this requirement by incorporating batteries -
and with the continued miniaturization of computing resources and advancements
in portable battery life, portable computers grew in popularity in the 2000s.
The same developments allowed manufacturers to integrate computing resources
into cellular phones. These smartphones and tablets run on a variety
of operating systems and soon became the dominant computing device on the
market, with manufacturers reporting having shipped an estimated 237 million
devices in 2Q 2013.
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