father of computers-Charles Babbage

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By Matrixkavi

Charles Babbage, a British Mathematics professor, is regarded as the Father of Computers. He was born in England in 1792 as the son of a rich banker from Devon. He was inspired by Napier's logarithm tables and Napier's logs and bones. He began to design a "difference engine" in 1821 which was a very large and complicated machine intended for doing logarithmic calculations automatically.
The device was based on the principle that the difference between certain values of the expression at a certain stage becomes constant. But it was difficult to make the machine parts accurate enough to prevent errors to occur, using the technology available at that time.
Encouraged by the work of "difference engine", he began design of another machine "the analytical machine", which could carry out many different types of calculations. Analytical engine used the concepts of Automatic Loom and Difference Engine.
The Analytical machine had five units- input, output, store, mill, and control. Store was used for storing numbers and Mill was used to do the calculations by rotation of gears and wheels. Control unit did the job of supervision of all other units. Note that these five units are similar to the functional units of a modern digital computer.No wonder he was called the "Father of Computers"!

 

 

The father of the computer

Few would deny that the invention of the computer has revolutionized society or that the world of today would look quite different without computers. In the relatively short span of time that has elapsed since the world's first electronic digital computer was invented in 1939, computers have become universal tools that are an integral part of modern life. Yet, comparatively few people know that John Atanasoff, the genius who invented the first computer and initiated the computer revolution, was of Bulgarian ancestry. John Atanasoff was a prominent American inventor who took pride in his Bulgarian heritage and maintained strong ties to his ancestral home of Bulgaria.
John Atanasoff's father, Ivan Atanasoff, was born in the village of Boyadjick, Bulgaria. Ivan Atanasoff had lost his own father in 1876, when the latter was brutally killed in the April Uprising of the Bulgarians against the Ottoman Empire. In 1889, when Ivan Atanasoff was thirteen years old, he emmigrated to the United States accompanied by an uncle. He later married Iva Lucena. John Vincent Atanasoff was born in the town of Hamilton, New York on October 4, 1903.
It was recognized early that John Atanasoff had both a passion and talent for mathematics. His youthful interest in baseball was quickly forgotten once his father showed him the logarithmic slide rule he had bought for facilitating engineering calculations. The slide rule completely captivated the nine-year-old boy, who spent hours studying the instructions and delighting in the fact that this mathematical tool consistently resulted in correct solutions to problems.
John Atanasoff completed his high school course in two years, with excellence in both science and mathematics. He graduated from the University of Florida in Gainesville in 1925, with a Bachelor of Science degree in electrical engineering. He received his Master's degree in mathematics from the Iowa State College in Ames, Iowa in 1926. After completing his graduate studies, Atanasoff accepted a position teaching physics and mathematics at Iowa State College. He was then accepted into the doctoral program at the University of Wisconsin, and received his doctoral degree (Ph. D.) in theoretical physics from Wisconsin in 1930. Atanasoff was required to do many complicated and time consuming computations. Although he utilized the Monroe mechanical calculator, one of the best machines of the time, to assist in his tedious computations, the shortcomings of this machine were painfully obvious and motivated him to think about the possibility of developing a more sophisticated calculating machine. After receiving his Ph. D. in theoretical physics in July 1930, John returned to the staff of Iowa State College and began his work on developing a better and faster computing machine.
In the late 1930s, John Atanasoff was still trying to develop ways to facilitate the process of calculating solutions to the extended systems of linear algebraic equations that were applicable to his research work. He became convinced that the digital approach offered considerable advantages over the slower and less accurate analog machines. In December of 1939, working with his graduate student Clifford Berry, John Atanasoff developed and built the prototype of the first electronic digital computer, which would be fully completed in 1942. This prototype of the first computer included four significant and entirely novel operating principles in its operation: The binary system, regenerative data storage, logic circuits as elements of a program, and electronic elements as data carrying media
"After the prototype had started working, we were convinced we could build a computer capable of calculating whatever we would like to", wrote Atanasoff. Having demonstrated the viability of the four major principles, the prototype unequivocally opened the way for all present day computers.
In their history of the ENIAC computer, Alice R. Burks and Arthur W. Burks summarize the Atanasoff achievement as follows: "He invented a new type of a serial storage module, applicable to digital electronic computing. He formulated, developed and proved the major principles involved in electronic circuits for digital computing, principles that included arithmetical operations, control, transition from one to another number base systems, transfer and storage of data, and synchronized clocking of the operations. Having applied that data storage and those principles, he constructed a well-balanced electronic computer with centralized architecture, including storage, and arithmetically controlled input/output devices. He had invented the first-ever specialized electronic computer with such a degree of multi-aspect applicability."
The ABC computer would have been fully operative by 1943, had the efforts of John Atanasoff and Clifford Berry not been interrupted by World War II. In September of 1942, Atanasoff was conscripted into the military and was forced to set aside his work on the computer. He began working at the Naval Ordnance Laboratory (NOL), a research laboratory at the Armed Forces Ordnance Administration, where, as a theoretical physicist, he was put in charge of testing acoustic mines, depth charges, and other similar projects.
A significant event had occurred in 1941, when Atanasoff received a colleague, John W. Mauchly, into his home as a guest. Mauchly had expressed great interest in the work Atanasoff was doing relating to computer technology and had enthusiastically accepted Atanasoff's invitation. It is important to ask exactly what transpired during this visit between Atanasoff and Mauchly, since the events that resulted from the time they spent together are now etched in history. The facts were examined in detail at a judicial hearing 26 years later, when the courts had to decide whether John W. Mauchly and John P. Eckert had unlawfully made use of Atanasoff's invention when they developed the ENIAC computer between 1942 and 1946. Before this time, the ENIAC had been recognized as the first electronic computer, but the facts of the case would prove otherwise.
On October 19, 1973, Judge Earl R. Larson made public his ruling on the ENIAC case. According to the US statutory judicial procedure, Justice Larson issued a court ruling on the merits of the evidence, a summation, and a court verdict, which resulted in a total of 420 pages of material. The court verdict said: "With this Verdict the Court has ruled that the Patent of ENIAC - US Patent, Serial No. 3 120 606, issued to the Illinois Scientific Developments Incorporated, is hereby declared null and void."
The Federal Judge ruled that Mauchly derived the basic ideas for an electronic digital computer from the Atanasoff-Berry computer. He also ruled that John Atanasoff and Clifford Berry were the first to have constructed an electronic digital computer at the Iowa State College in the years between 1939 and 1942. In addition, the judge ruled that John Mauchly and John Eckert, who had for over 25 years been the recipients of recognition and admiration as co-inventors of the first electronic digital computer, had, in fact, lost all rights to the patent upon which all of the praise had been based. "Eckert and Mauchly had not invented the first automated electronic digital computer, but had derived the basic ideas for it by John Atanasoff." (Excerpt of the Summation of the Court in Minneapolis, 1973).
"The principles of John Atanasoff's computer, though seemingly outdated today, are the basis of the thousands of millions of computers, without which modern society cannot exist. Every Bulgarian knows and prides in the holy brothers, St. Cyrille and St. Methodius, who created the alphabet of most Slavonic peoples. Similarly, John Atanasoff, a man of Bulgarian extraction, opened the road to the world information society." (Acad. Blaghovest Sendov - 20 April 2001).
"Devoting this version of my memoirs to the people of my fatherland, I feel great excitement. I need to tell my Bulgarian readers too many things but words do not come easily.
My father was born on January 6, 1876, at the time of the preparation of our people for an uprising against the Turks. Before the outbreak of the uprising, the Turkish governors forced the people of the village of Boyadjik (present Boyadjik, Yambol Region) to leave their houses and then they burnt them. As my grandfather ran with his son in his hands, followed by my grandmother, a group of Turkish soldiers shot him in the chest. The bullet, which killed him, left a scar on the forehead of my father for the rest of his life.
My grandmother married twice more after that. My father was 13 years old when he arrived in the United States and at 15 he became an orphan. After this incredible start in his life, he finished the Colgate University and married my mother, an American whose grandfather fought in the Civil War between the North and the South.
I have always felt that the heritage of the two peoples in my blood has kept my spirit. And now, as I am growing old, I am even happier for my good fortune. My father's people have met me warmly and have given me a high prize the Cyrille and Methodius Order (First Class). I was elected a foreign member of the Bulgarian Academy of Sciences and I am in touch with many friends in Bulgaria."

John Atanasoff
( 1903 - 1995) More about the topic. 

Alan Turing

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"Turing" redirects here. For other uses, see Turing (disambiguation).

Alan Mathison Turing
Born	23 June 1912(1912-06-23) Maida Vale, London, England, United Kingdom
Died	7 June 1954(1954-06-07) (aged 41) Wilmslow, Cheshire, England, United Kingdom
Residence	United Kingdom
Nationality	British
Fields	Mathematics, Cryptanalysis, Computer science
Institutions	University of Cambridge Government Code and Cypher School National Physical Laboratory University of Manchester
Alma mater	King's College, Cambridge Princeton University
Doctoral advisor	Alonzo Church
Doctoral students	Robin Gandy
Known for	Halting problem Turing machine Cryptanalysis of the Enigma Automatic Computing Engine Turing Award Turing Test Turing patterns
Notable awards	Officer of the Order of the British Empire Fellow of the Royal Society

Alan Mathison Turing, OBE, FRS ( /ˈtjʊərɪŋ/ tewr-ing; 23 June 1912 – 7 June 1954), was an English mathematician, logician, cryptanalyst and computer scientist. He was highly influential in the development of computer science, providing a formalisation of the concepts of "algorithm" and "computation" with the Turing machine, which played a significant role in the creation of the modern computer.^[1][2] Turing is widely considered to be the father of computer science and artificial intelligence.^[3]
During the Second World War, Turing worked for the Government Code and Cypher School at Bletchley Park, Britain's codebreaking centre. For a time he was head of Hut 8, the section responsible for German naval cryptanalysis. He devised a number of techniques for breaking German ciphers, including the method of the bombe, an electromechanical machine that could find settings for the Enigma machine. After the war he worked at the National Physical Laboratory, where he created one of the first designs for a stored-program computer, the ACE.
Towards the end of his life Turing became interested in mathematical biology. He wrote a paper on the chemical basis of morphogenesis,^[4] and he predicted oscillating chemical reactions such as the Belousov–Zhabotinsky reaction, which were first observed in the 1960s.
Turing's homosexuality resulted in a criminal prosecution in 1952, when homosexual acts were still illegal in the United Kingdom. He accepted treatment with female hormones (chemical castration) as an alternative to prison. He died in 1954, just over two weeks before his 42nd birthday, from cyanide poisoning. An inquest determined it was suicide; his mother and some others believed his death was accidental. On 10 September 2009, following an Internet campaign, British Prime Minister Gordon Brown made an official public apology on behalf of the British government for the way in which Turing was treated after the war.^[5]

Contents [hide] 1 Childhood and youth 2 University and work on computability 3 Cryptanalysis 3.1 Turing–Welchman bombe 3.2 Hut 8 and Naval Enigma 4 Early computers and the Turing test 5 Pattern formation and mathematical biology 6 Conviction for indecency 7 Death 7.1 Epitaph 8 Recognition and tributes 8.1 Government apology 8.2 Tributes by universities 8.3 Centenary commemoration 9 See also 10 Notes 11 References 12 Further reading 13 External links 13.1 Papers

[edit] Childhood and youth

Alan Turing was conceived in India.^[6] His father, Julius Mathison Turing, was a member of the Indian Civil Service. Julius and wife Ethel Sara Stoney (1881–1976, daughter of Edward Waller Stoney, chief engineer of the Madras Railways) wanted Alan to be brought up in England, so they returned to Maida Vale,^[7] London, where Alan Turing was born on 23 June 1912, as recorded by a blue plaque on the outside of the building,^[8] later the Colonnade Hotel.^[6][9] He had an elder brother, John. His father's civil service commission was still active, and during Turing's childhood years his parents travelled between Hastings, England^[10] and India, leaving their two sons to stay with a retired Army couple. Very early in life, Turing showed signs of the genius he was to later prominently display.^[11]
His parents enrolled him at St Michael's, a day school at 20 Charles Road, St Leonards on Sea, at the age of six. The headmistress recognised his talent early on, as did many of his subsequent educators. In 1926, at the age of 14, he went on to Sherborne School, a famous independent school in the market town of Sherborne in Dorset. His first day of term coincided with the General Strike in Britain, but so determined was he to attend his first day that he rode his bicycle unaccompanied more than 60 miles (97 km) from Southampton to school, stopping overnight at an inn.^[12]

King's College, Cambridge, where the computer room is named after Turing, who became a student there in 1931 and a Fellow in 1935

Turing's natural inclination toward mathematics and science did not earn him respect with some of the teachers at Sherborne, whose definition of education placed more emphasis on the classics. His headmaster wrote to his parents: "I hope he will not fall between two stools. If he is to stay at Public School, he must aim at becoming educated. If he is to be solely a Scientific Specialist, he is wasting his time at a Public School".^[13] Despite this, Turing continued to show remarkable ability in the studies he loved, solving advanced problems in 1927 without having even studied elementary calculus. In 1928, aged 16, Turing encountered Albert Einstein's work; not only did he grasp it, but he extrapolated Einstein's questioning of Newton's laws of motion from a text in which this was never made explicit.^[14]
Turing's hopes and ambitions at school were raised by the close friendship he developed with a slightly older fellow student, Christopher Morcom, who was Turing's first love interest. Morcom died suddenly only a few weeks into their last term at Sherborne, from complications of bovine tuberculosis, contracted after drinking infected cow's milk as a boy.^[15] Turing's religious faith was shattered and he became an atheist. He adopted the conviction that all phenomena, including the workings of the human brain, must be materialistic,^[16] but he still believed in the survival of the spirit after death.^[17]

[edit] University and work on computability

Alan Turing memorial statue in Sackville Park, Manchester

After Sherborne, Turing went to study at King's College, Cambridge. He was an undergraduate there from 1931 to 1934, graduating with first-class honours in Mathematics, and in 1935 was elected a fellow at King's on the strength of a dissertation on the central limit theorem.^[18]
In 1928, German mathematician, David Hilbert had called attention to the Entscheidungsproblem (decision problem). In his momentous paper "On Computable Numbers, with an Application to the Entscheidungsproblem" (submitted on 28 May 1936 and delivered 12 November),^[19] Turing reformulated Kurt Gödel's 1931 results on the limits of proof and computation, replacing Gödel's universal arithmetic-based formal language with what became known as Turing machines, formal and simple devices. He proved that some such machine would be capable of performing any conceivable mathematical computation if it were representable as an algorithm. He went on to prove that there was no solution to the Entscheidungsproblem by first showing that the halting problem for Turing machines is undecidable: it is not possible to decide, in general, algorithmically whether a given Turing machine will ever halt. While his proof was published subsequent to Alonzo Church's equivalent proof in respect to his lambda calculus, Turing was unaware of Church's work at the time.
In his memoirs Turing wrote that he was disappointed about the reception of this 1936 paper and that only two people had reacted – these being Heinrich Scholz and Richard Bevan Braithwaite.
Turing's approach is considerably more accessible and intuitive. It was also novel in its notion of a 'Universal (Turing) Machine', the idea that such a machine could perform the tasks of any other machine. Or in other words, is provably capable of computing anything that is computable. Turing machines are to this day a central object of study in theory of computation.
The paper also introduces the notion of definable numbers.
From September 1936 to July 1938 he spent most of his time at the Institute for Advanced Study, Princeton, New Jersey, studying under Alonzo Church. As well as his pure mathematical work, he studied cryptology and also built three of four stages of an electro-mechanical binary multiplier.^[20] In June 1938 he obtained his PhD from Princeton; his dissertation (Systems of Logic Based on Ordinals) introduced the concept of ordinal logic and the notion of relative computing, where Turing machines are augmented with so-called oracles, allowing a study of problems that cannot be solved by a Turing machine.
Back in Cambridge, he attended lectures by Ludwig Wittgenstein about the foundations of mathematics.^[21] The two argued and disagreed, with Turing defending formalism and Wittgenstein arguing that mathematics does not discover any absolute truths but rather invents them.^[22] He also started to work part-time with the Government Code and Cypher School (GCCS).

[edit] Cryptanalysis

Two cottages in the stable yard at Bletchley Park. Turing worked here from 1939 to 1940, when he moved to Hut 8.

During the Second World War, Turing was a main participant in the efforts at Bletchley Park to break German ciphers. Building on cryptanalysis work carried out in Poland by Marian Rejewski, Jerzy Różycki and Henryk Zygalski from Cipher Bureau before the war, he contributed several insights into breaking both the Enigma machine and the Lorenz SZ 40/42 (a Teleprinter (Teletype) cipher attachment codenamed Tunny by the British), and was, for a time, head of Hut 8, the section responsible for reading German naval signals.
From September 1938, Turing had been working part-time (notionally for the British Foreign Office) with the Government Code and Cypher School (GCCS), the British code breaking organisation. He worked on the problem of the German Enigma machine, and collaborated with Dilly Knox, a senior GCCS codebreaker.^[23] On 4 September 1939, the day after the UK declared war on Germany, Turing reported to Bletchley Park, the wartime station of GCCS.^[24]
In 1945, Turing was awarded the OBE for his wartime services, but his work remained secret for many years.
Turing had something of a reputation for eccentricity at Bletchley Park. Jack Good, a cryptanalyst who worked with him, is quoted by Ronald Lewin as having said of Turing:

in the first week of June each year he would get a bad attack of hay fever, and he would cycle to the office wearing a service gas mask to keep the pollen off. His bicycle had a fault: the chain would come off at regular intervals. Instead of having it mended he would count the number of times the pedals went round and would get off the bicycle in time to adjust the chain by hand. Another of his eccentricities is that he chained his mug to the radiator pipes to prevent it being stolen.^[25]

While working at Bletchley, Turing, a talented long-distance runner, occasionally ran the 40 miles (64 km) to London when he was needed for high-level meetings,^[26] and he was capable of world-class marathon standards.^[27]

[edit] Turing–Welchman bombe

Within weeks of arriving at Bletchley Park,^[24] Turing had specified an electromechanical machine which could help break Enigma faster than bomba from 1938, the bombe, named after and building upon the original Polish-designed bomba. The bombe, with an enhancement suggested by mathematician Gordon Welchman, became one of the primary tools, and the major automated one, used to attack Enigma-protected message traffic.

A complete and working replica of a bombe at Bletchley Park

Jack Good opined:

Turing's most important contribution, I think, was of part of the design of the bombe, the cryptanalytic machine. He had the idea that you could use, in effect, a theorem in logic which sounds to the untrained ear rather absurd; namely that from a contradiction, you can deduce everything.^[28]

The bombe searched for possibly correct settings used for an Enigma message (i.e., rotor order, rotor settings, etc.), and used a suitable crib: a fragment of probable plaintext. For each possible setting of the rotors (which had of the order of 10¹⁹ states, or 10²² for the four-rotor U-boat variant),^[29] the bombe performed a chain of logical deductions based on the crib, implemented electrically. The bombe detected when a contradiction had occurred, and ruled out that setting, moving onto the next. Most of the possible settings would cause contradictions and be discarded, leaving only a few to be investigated in detail. Turing's bombe was first installed on 18 March 1940.^[30] More than two hundred bombes were in operation by the end of the war.^[31]

[edit] Hut 8 and Naval Enigma

Statue of Turing by Stephen Kettle at Bletchley Park, commissioned by the American philanthropist Sidney E Frank.^[32]

Turing decided to tackle the particularly difficult problem of German naval Enigma "because no one else was doing anything about it and I could have it to myself".^[33] In December 1939, Turing solved the essential part of the naval indicator system, which was more complex than the indicator systems used by the other services.^[33][34] The same night that he solved the naval indicator system, he conceived the idea of Banburismus, a sequential statistical technique (what Abraham Wald later called sequential analysis) to assist in breaking naval Enigma, "though I was not sure that it would work in practice, and was not in fact sure until some days had actually broken".^[33] For this he invented a measure of weight of evidence that he called the Ban. Banburismus could rule out certain orders of the Enigma rotors, substantially reducing the time needed to test settings on the bombes.
In 1941, Turing proposed marriage to Hut 8 co-worker Joan Clarke, a fellow mathematician, but their engagement was short-lived. After admitting his homosexuality to his fiancée, who was reportedly "unfazed" by the revelation, Turing decided that he could not go through with the marriage.^[35]
In July 1942, Turing devised a technique termed Turingery (or jokingly Turingismus)^[36] for use against the Lorenz cipher messages produced by the Germans' new Geheimschreiber machine (secret writer). This was codenamed Tunny at Bletchley Park. He also introduced the Tunny team to Tommy Flowers who, under the guidance of Max Newman, went on to build the Colossus computer, the world's first programmable digital electronic computer, which replaced a simpler prior machine (the Heath Robinson) and whose superior speed allowed the brute-force decryption techniques to be applied usefully to the daily changing cyphers.^[37] A frequent misconception is that Turing was a key figure in the design of Colossus; this was not the case.^[38]
Turing travelled to the United States in November 1942 and worked with U.S. Navy cryptanalysts on Naval Enigma and bombe construction in Washington, and assisted at Bell Labs with the development of secure speech devices. He returned to Bletchley Park in March 1943. During his absence, Hugh Alexander had officially assumed the position of head of Hut 8, although Alexander had been de facto head for some time—Turing having little interest in the day-to-day running of the section. Turing became a general consultant for cryptanalysis at Bletchley Park.
Alexander wrote as follows about his contribution:

There should be no question in anyone's mind that Turing's work was the biggest factor in Hut 8's success. In the early days he was the only cryptographer who thought the problem worth tackling and not only was he primarily responsible for the main theoretical work within the Hut but he also shared with Welchman and Keen the chief credit for the invention of the Bombe. It is always difficult to say that anyone is absolutely indispensable but if anyone was indispensable to Hut 8 it was Turing. The pioneer's work always tends to be forgotten when experience and routine later make everything seem easy and many of us in Hut 8 felt that the magnitude of Turing's contribution was never fully realised by the outside world.^[39]

In the latter part of the war he moved to work at Hanslope Park, where he further developed his knowledge of electronics with the assistance of engineer Donald Bayley. Together they undertook the design and construction of a portable secure voice communications machine codenamed Delilah.^[40] It was intended for different applications, lacking capability for use with long-distance radio transmissions, and in any case, Delilah was completed too late to be used during the war. Though Turing demonstrated it to officials by encrypting/decrypting a recording of a Winston Churchill speech, Delilah was not adopted for use. Turing also consulted with Bell Labs on the development of SIGSALY, a secure voice system that was used in the later years of the war.

[edit] Early computers and the Turing test

From 1945 to 1947 Turing lived in Church Street, Hampton^[41] while he worked on the design of the ACE (Automatic Computing Engine) at the National Physical Laboratory. He presented a paper on 19 February 1946, which was the first detailed design of a stored-program computer.^[42] Although ACE was a feasible design, the secrecy surrounding the wartime work at Bletchley Park led to delays in starting the project and he became disillusioned. In late 1947 he returned to Cambridge for a sabbatical year. While he was at Cambridge, the Pilot ACE was built in his absence. It executed its first program on 10 May 1950.
In 1948, he was appointed Reader in the Mathematics Department at Manchester (now part of The University of Manchester). In 1949, he became Deputy Director of the computing laboratory at the University of Manchester, and worked on software for one of the earliest stored-program computers—the Manchester Mark 1. During this time he continued to do more abstract work, and in "Computing machinery and intelligence" (Mind, October 1950), Turing addressed the problem of artificial intelligence, and proposed an experiment which became known as the Turing test, an attempt to define a standard for a machine to be called "intelligent". The idea was that a computer could be said to "think" if a human interrogator could not tell it apart, through conversation, from a human being.^[43] In the paper, Turing suggested that rather than building a program to simulate the adult mind, it would be better rather to produce a simpler one to simulate a child's mind and then to subject it to a course of education. A reversed form of the Turing test is widely used on the Internet; the CAPTCHA test is intended to determine whether the user is a human or a computer.
In 1948, Turing, working with his former undergraduate colleague, D. G. Champernowne, began writing a chess program for a computer that did not yet exist. In 1952, lacking a computer powerful enough to execute the program, Turing played a game in which he simulated the computer, taking about half an hour per move. The game was recorded.^[44] The program lost to Turing's colleague Alick Glennie, although it is said that it won a game against Champernowne's wife.
His Turing test was a significant and characteristically provocative and lasting contribution to the debate regarding artificial intelligence, which continues after more than half a century.^[45]
He also invented the LU decomposition method used today for solving an equations matrix in 1948.^[46]

[edit] Pattern formation and mathematical biology

Turing worked from 1952 until his death in 1954 on mathematical biology, specifically morphogenesis. He published one paper on the subject called The Chemical Basis of Morphogenesis in 1952, putting forth the Turing hypothesis of pattern formation.^[47] His central interest in the field was understanding Fibonacci phyllotaxis, the existence of Fibonacci numbers in plant structures. He used reaction–diffusion equations which are central to the field of pattern formation. Later papers went unpublished until 1992 when Collected Works of A.M. Turing was published. His contribution is considered a seminal piece of work in this field.^[48]

[edit] Conviction for indecency

In January 1952, Turing met Arnold Murray outside a cinema in Manchester. After a lunch date, Turing invited Murray to spend the weekend with him at his house, an invitation which Murray accepted although he did not show up. The pair met again in Manchester the following Monday, when Murray agreed to accompany Turing to the latter's house. A few weeks later Murray visited Turing's house again, and apparently spent the night there.^[49]
After Murray helped an accomplice to break into his house, Turing reported the crime to the police. During the investigation, Turing acknowledged a sexual relationship with Murray. Homosexual acts were illegal in the United Kingdom at that time,^[50] and so both were charged with gross indecency under Section 11 of the Criminal Law Amendment Act 1885, the same crime for which Oscar Wilde had been convicted more than fifty years earlier.^[51]
Turing was given a choice between imprisonment or probation conditional on his agreement to undergo hormonal treatment designed to reduce libido. He accepted chemical castration via oestrogen hormone injections.^[52]
Turing's conviction led to the removal of his security clearance, and barred him from continuing with his cryptographic consultancy for GCHQ. His British passport was not revoked, though he was denied entry to the United States after his conviction.^{[citation needed]} At the time, there was acute public anxiety about spies and homosexual entrapment by Soviet agents,^[53] because of the recent exposure of the first two members of the Cambridge Five, Guy Burgess and Donald Maclean, as KGB double agents. Turing was never accused of espionage but, as with all who had worked at Bletchley Park, was prevented from discussing his war work.^[54]

[edit] Death

On 8 June 1954, Turing's cleaner found him dead; he had died the previous day. A post-mortem examination established that the cause of death was cyanide poisoning. When his body was discovered an apple lay half-eaten beside his bed, and although the apple was not tested for cyanide,^[55] it is speculated that this was the means by which a fatal dose was delivered. An inquest determined that he had committed suicide, and he was cremated at Woking Crematorium on 12 June 1954.^[56] Turing's mother argued strenuously that the ingestion was accidental, caused by her son's careless storage of laboratory chemicals. Biographer Andrew Hodges suggests that Turing may have killed himself in an ambiguous way quite deliberately, to give his mother some plausible deniability.^[57] David Leavitt has suggested that Turing was re-enacting a scene from the 1937 film Snow White, his favourite fairy tale, pointing out that he took "an especially keen pleasure in the scene where the Wicked Witch immerses her apple in the poisonous brew."^[58]

[edit] Epitaph

Hyperboloids of wondrous Light
Rolling for aye through Space and Time
Harbour those Waves which somehow Might
Play out God's holy pantomime ^[59]

[edit] Recognition and tributes

A Blue Plaque marking Turing's home at Wilmslow, Cheshire

A biography published by the Royal Society shortly after Turing's death (and while his wartime work was still subject to the Official Secrets Act) recorded:

Three remarkable papers written just before the war, on three diverse mathematical subjects, show the quality of the work that might have been produced if he had settled down to work on some big problem at that critical time. For his work at the Foreign Office he was awarded the OBE.

—^[1]

Since 1966, the Turing Award has been given annually by the Association for Computing Machinery to a person for technical contributions to the computing community. It is widely considered to be the computing world's highest honour, equivalent to the Nobel Prize.^[60]
Breaking the Code is a 1986 play by Hugh Whitemore about Alan Turing. The play ran in London's West End beginning in November 1986 and on Broadway from 15 November 1987 to 10 April 1988. There was also a 1996 BBC television production. In all cases, Derek Jacobi played Turing. The Broadway production was nominated for three Tony Awards including Best Actor in a Play, Best Featured Actor in a Play, and Best Direction of a Play, and for two Drama Desk Awards, for Best Actor and Best Featured Actor.
On 23 June 1998, on what would have been Turing's 86th birthday, Andrew Hodges, his biographer, unveiled an official English Heritage Blue Plaque at his birthplace and childhood home in Warrington Crescent, London, later the Colonnade hotel.^[61][62] To mark the 50th anniversary of his death, a memorial plaque was unveiled on 7 June 2004 at his former residence, Hollymeade, in Wilmslow, Cheshire.^[63]
On 13 March 2000, Saint Vincent and the Grenadines issued a set of stamps to celebrate the greatest achievements of the twentieth century, one of which carries a recognisable portrait of Turing against a background of repeated 0s and 1s, and is captioned: "1937: Alan Turing's theory of digital computing".
On 28 October 2004, a bronze statue of Alan Turing sculpted by John W Mills was unveiled at the University of Surrey in Guildford, marking the 50th anniversary of Turing's death; it portrays him carrying his books across the campus.^[64]
In 2006, Boston Pride named Turing their Honorary Grand Marshal.^[65]
Turing was one of four mathematicians examined in the 2008 BBC documentary entitled "Dangerous Knowledge".^[66]
The Princeton Alumni Weekly named Turing the second most significant alumnus in the history of Princeton University, second only to President James Madison.
A 1.5-ton, life-size statue of Turing was unveiled on 19 June 2007 at Bletchley Park. Built from approximately half a million pieces of Welsh slate, it was sculpted by Stephen Kettle, having been commissioned by the late American billionaire Sidney Frank.^[67]
Turing has been honoured in various ways in Manchester, the city where he worked towards the end of his life. In 1994, a stretch of the A6010 road (the Manchester city intermediate ring road) was named Alan Turing Way. A bridge carrying this road was widened, and carries the name Alan Turing Bridge. A statue of Turing was unveiled in Manchester on 23 June 2001. It is in Sackville Park, between the University of Manchester building on Whitworth Street and the Canal Street gay village. The memorial statue, depicts the "father of Computer Science" sitting on a bench at a central position in the park. The statue was unveiled on Turing's birthday.

Turing memorial statue plaque in Sackville Park, Manchester

Turing is shown holding an apple—a symbol classically used to represent forbidden love, the object that inspired Isaac Newton's theory of gravitation, and the means of Turing's own death. The cast bronze bench carries in relief the text 'Alan Mathison Turing 1912–1954', and the motto 'Founder of Computer Science' as it would appear if encoded by an Enigma machine: 'IEKYF ROMSI ADXUO KVKZC GUBJ'.
A plinth at the statue's feet says 'Father of computer science, mathematician, logician, wartime codebreaker, victim of prejudice'. There is also a Bertrand Russell quotation saying 'Mathematics, rightly viewed, possesses not only truth, but supreme beauty—a beauty cold and austere, like that of sculpture.' The sculptor buried his old Amstrad computer, which was an early popular home computer, under the plinth, as a tribute to "the godfather of all modern computers".^[68]
In 1999, Time Magazine named Turing as one of the 100 Most Important People of the 20th Century for his role in the creation of the modern computer, and stated: "The fact remains that everyone who taps at a keyboard, opening a spreadsheet or a word-processing program, is working on an incarnation of a Turing machine."^[2] Turing is featured in the 1999 Neal Stephenson novel "Cryptonomicon."
In 2002, Turing was ranked twenty-first on the BBC nationwide poll of the 100 Greatest Britons.^[69]
The logo of Apple computer is often erroneously referred to as a tribute to Alan Turing, with the bite mark a reference to his method of suicide.^[70] Both the designer of the logo^[71] and the company deny that there is any homage to Turing in the design of the logo.^[72]
In 2010, actor/playwright Jade Esteban Estrada portrayed Turing in the solo musical, "ICONS: The Lesbian and Gay History of the World, Vol. 4."
Turing is mentioned several times in the DLC for the 2K Games "Bioshock 2" He is mentioned several times by the voice actor who portrays C.M. Porter. There is also a telegram in Porter's office requesting he come to London and work with Turing. He is also mentioned in Assassin's Creed: Brotherhood, when an employee of Abstergo Industries orders him to be killed and commands the would-be executioner to "make it look biblical".
In February 2011, Turing's papers from the Second World War were bought for the nation with an 11th-hour bid by the National Heritage Memorial Fund, allowing them to stay at Bletchley Park.^[73]

[edit] Government apology

In August 2009, John Graham-Cumming started a petition urging the British Government to posthumously apologise to Alan Turing for prosecuting him as a homosexual.^[74][75] The petition received thousands of signatures.^[76][77] Prime Minister Gordon Brown acknowledged the petition, releasing a statement on 10 September 2009 apologising and describing Turing's treatment as "appalling":^[5][76]

Thousands of people have come together to demand justice for Alan Turing and recognition of the appalling way he was treated. While Turing was dealt with under the law of the time and we can't put the clock back, his treatment was of course utterly unfair and I am pleased to have the chance to say how deeply sorry I and we all are for what happened to him ... So on behalf of the British government, and all those who live freely thanks to Alan's work I am very proud to say: we're sorry, you deserved so much better.^[76]

[edit] Tributes by universities

The Alan Turing Building at the University of Manchester

A celebration of Turing's life and achievements arranged by the British Logic Colloquium and the British Society for the History of Mathematics was held on 5 June 2004.

• The University of Surrey has a statue of Turing on their main piazza.
• Istanbul Bilgi University organises an annual conference on the theory of computation called "Turing Days".^[78]
• The University of Texas at Austin has an honours computer science programme named the Turing Scholars.^[79]
• In the early 1960s Stanford University named the sole lecture room of the Polya Hall Mathematics building "Alan Turing Auditorium".^[80]
• One of the amphitheatres of the Computer Science department (LIFL^[81]) at the University of Lille in northern France is named in honour of Alan M. Turing (the other amphitheatre is named after Kurt Gödel).
• The Department of Computer Science at Pontifical Catholic University of Chile, the Polytechnic University of Puerto Rico, Los Andes University in Bogotá, Colombia, King's College, Cambridge and Bangor University in Wales have computer laboratories named after Turing.
• The University of Manchester, The Open University, Oxford Brookes University and Aarhus University (in Århus, Denmark) all have buildings named after Turing.
• Alan Turing Road in the Surrey Research Park is named for Alan Turing.
• Carnegie Mellon University has a granite bench, situated in The Hornbostel Mall, with the name "A. M. Turing" carved across the top, "Read" down the left leg, and "Write" down the other.
• The École Internationale des Sciences du Traitement de l'Information has named its recently acquired third building "Turing".
• The University of Ghent has one of its main computer rooms (in a building used mostly by mathematicians and computing scientists) named for Alan Turing.
• The University of Oregon has a bust of Turing on the side of the Deschutes Hall, the computer science building.

[edit] Centenary commemoration

To mark the 100th anniversary of Turing's birth, the Turing Centenary Advisory Committee (TCAC) is coordinating the Alan Turing Year, a year-long programme of events around the world honouring Turing's life and achievements. The TCAC working with The University of Manchester faculty members and a broad spectrum of people from Cambridge University and Bletchley Park, is chaired by S. Barry Cooper, with Alan Turing's nephew Sir John Dermot Turing acting as TCAC Honorary President.
Events are scheduled in many countries around the world including the USA, Brazil, China, Czech Republic, the Philippines, New Zealand, Israel, Spain, Norway, Italy, Portugal and Germany. The keystone events will be a three-day conference in Manchester, UK in June examining Turing's mathematical and code-breaking achievements, and a Turing Centenary Conference in Cambridge organised by King's College, Cambridge and the association Computability in Europe.^[82]

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