Charles
Babbage
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Charles Babbage in 1860 |
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Born
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26 December 1791
London, England |
Died
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18 October
1871 (aged 79)
Marylebone, London, England |
Nationality
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English
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Fields
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Mathematics, engineering,
political economy, computer science
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Institutions
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Known for
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Mathematics, computing
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Influences
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Influenced
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Signature
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Charlse Babbage
Charles Babbage, FRS (26 December 1791 – 18
October 1871) was an English polymath. He was a mathematician,
philosopher, inventor and mechanical engineer, who is best remembered now for
originating the concept of a programmable computer.
Considered a "father of the computer", Babbage is credited with inventing
the first mechanical
computer that eventually led to more complex designs.
His varied work in other fields has led him to be described as
"pre-eminent" among the many polymaths of his century.
In 1991, a perfectly functioning difference engine was constructed from
Babbage's original plans. Built to tolerances achievable in the 19th
century, the success of the finished engine indicated that Babbage's machine would have worked.
Early life
Babbage's birthplace is disputed, but
according to the Oxford Dictionary of National Biography he was most likely born at
44 Crosby Row, Walworth Road, London, England. A blue plaque on the junction of Larcom
Street and Walworth Road commemorates the event.
His date of birth was given in his obituary
in The Times as 26 December 1792; but
then a nephew wrote to say that Babbage was born one year earlier, in 1791. The
parish register of St. Mary's Newington, London, shows that Babbage was baptized on 6 January 1792,
supporting a birth year of 1791.
The Illustrated London News (4 November 1871).
Babbage was one of four children of Benjamin
Babbage and Betsy Plumleigh Teape. His father was a banking partner of William Praed in founding Praed's &
Co. of Fleet Street, London, in 1801. In 1808, the Babbage family
moved into the old Rowdens house in East Teignmouth. Around the age of eight
Babbage was sent to a country school in Alphington near Exeter to recover from a
life-threatening fever. For a short time he attended King Edward VI Grammar School in Totnes,
South Devon, but his health forced him back to private tutors for a time.
Babbage then joined the 30-student Holmwood
academy, in Baker Street, Enfield, Middlesex, under the Reverend
Stephen Freeman. The academy had a library that prompted Babbage's love of
mathematics. He studied with two more private tutors after leaving the academy.
The first was a clergyman near Cambridge; through him Babbage
encountered Charles Simeon and his evangelical followers,
but the tuition was not what he needed. He was brought home, to
study at the Totnes school: this was at age 16 or 17. The second was an Oxford
tutor, under whom Babbage reached a level in Classics sufficient to be accepted
by Cambridge.
At the University of
Cambridge
Babbage arrived at Trinity
College, Cambridge,
in October 1810. He was already self-taught in some parts of
contemporary mathematics; he had read in Robert Woodhouse, Joseph
Louis Lagrange,
and Marie Agnesi. As a result he was
disappointed in the standard mathematical instruction available at Cambridge.
Babbage, John Herschel, George Peacock, and several other friends
formed the Analytical
Society in 1812; they were also close to Edward Ryan. As a student, Babbage was
also a member of other societies such as The Ghost Club, concerned with
investigating supernatural phenomena, and the Extractors Club, dedicated to
liberating its members from the madhouse, should any be committed to one.
In 1812 Babbage transferred to Peterhouse,
Cambridge. He was the top
mathematician there, but did not graduate with honours. He instead received a
degree without examination in 1814. He had defended a thesis that was
considered blasphemous in the preliminary public disputation; but it is not
known whether this fact is related to his not sitting the examination.
After Cambridge
Considering only his reputation, Babbage
quickly made progress. He lectured to the Royal Institution on astronomy in 1815, and
was elected a Fellow
of the Royal Society in 1816. After graduation, on the
other hand, he applied for positions unsuccessfully, and had little in the way
of career. In 1816 he was a candidate for a teaching job at Haileybury College; he had
recommendations from James
Ivory and John Playfair, but lost out to Henry
Walter. In 1819, Babbage and
Herschel visited Paris and the Society
of Arcueil,
meeting leading French mathematicians and physicists. That year Babbage applied
to be professor at the University
of Edinburgh,
with the recommendation of Pierre
Simon Laplace;
the post went to William Wallace.
With Herschel, Babbage worked on the
electrodynamics of Arago's rotations,
publishing in 1825. Their explanations were only transitional, being picked up
and broadened by Michael Faraday. The phenomena are now
part of the theory of eddy currents, and Babbage and Herschel
missed some of the clues to unification of electromagnetic
theory,
staying close to AmpĆØre's force law.
Babbage purchased the actuarial tables of George
Barrett,
who died in 1821 leaving unpublished work, and surveyed the field in 1826 in Comparative View of the
Various Institutions for the Assurance of Lives. This interest followed a
project to set up an insurance company, prompted by Francis Baily and mooted in 1824, but not
carried out. Babbage did calculate actuarial tables for
that scheme, using Equitable Society mortality data from 1762
onwards.
During this whole period Babbage depended
awkwardly on his father's support, given his father's attitude to his early
marriage, of 1814: he and Edward Ryan wedded the Whitmore sisters. He made a
home in Marylebone in London, and founded a
large family. On his father's death in 1827, Babbage
inherited a large estate (value around £100,000), making him independently
wealthy. After his wife's death in the same year he
spent time travelling. In Italy he met Leopold II, Grand Duke of Tuscany, foreshadowing a later
visit to Piedmont. In April 1828 he was in Rome, and relying on
Herschel to manage the difference engine project, when he heard that he had
become professor at Cambridge, a position he had three times failed to obtain
(in 1820, 1823 and 1826).
The Astronomical Society
Babbage was instrumental in founding the Astronomical
Society in 1820. Its initial aims were to reduce
astronomical calculations to a more standard form, and to circulate data. These directions were
closely connected with Babbage's ideas on computation, and in 1824 he won its Gold Medal, cited "for his invention of an engine
for calculating mathematical and astronomical tables".
Babbage's motivation to overcome errors in
tables by mechanisation has been a commonplace since Dionysius Lardner wrote about it in 1834 in
the Edinburgh Review (under Babbage's guidance). The context of these
developments is still debated. Babbage's own account of the origin of the
difference engine begins with the Astronomical Society's wish to improve The
Nautical Almanac.
Babbage and Herschel were asked to oversee a trial project, to recalculate some
part of those tables. With the results to hand, discrepancies were found. This
was in 1821 or 1822, and was the occasion on which Babbage formulated his idea
for mechanical computation. The issue of the Nautical Almanac is now described as a
legacy of a polarisation in British science caused by attitudes to Sir Joseph Banks, who had died in 1820.
A portion of the difference
engine
Babbage studied the requirements to establish
a modern postal system, with his friend Thomas
Frederick Colby,
concluding there should be a uniform rate. Colby was another of the
founding group of the Society. He was also in charge of the Survey of Ireland. Herschel and Babbage were
present at a celebrated operation of that survey, the remeasuring of the Lough Foyle baseline.
The British Lagrangian School
The Analytical Society had initially been no
more than an undergraduate provocation. During this period it had some more
substantial achievements. In 1816 Babbage, Herschel and Peacock published a
translation from French of the lectures of Sylvestre Lacroix, which was then the state-of-the-art
calculus textbook.
Reference to Lagrange in calculus terms marks
out the application of what are now called formal
power series.
British mathematicians had used them from about 1730 to 1760. As re-introduced,
they were not simply applied as notations in differential
calculus.
They opened up the fields of functional
equations (including the difference
equations fundamental to the difference engine) and
operator (D-module) methods for differential
equations.
The analogy of difference and differential equations was notationally changing
Ī to D, as a "finite" difference becomes "infinitesimal".
These symbolic directions became popular, as operational
calculus,
and pushed to the point of diminishing returns. The Cauchy
concept of limit was kept at bay. Woodhouse had already
founded this second "British Lagrangian School" with its treatment of Taylor series as formal.
In this context function
composition is complicated to express, because the chain rule is not simply applied to
second and higher derivatives. This matter was known to Woodhouse by 1803, who
took from Louis François Antoine Arbogast what is now called Faà di Bruno's formula (a misnomer). In essence it
was known to Abraham De Moivre (1697). Herschel found the
method impressive, Babbage knew of it, and it was later noted by Lovelace as
compatible with the analytical engine. In the period to 1820
Babbage worked intensively on functional equations in general, and resisted
both conventional finite differences and Arbogast's approach (in
which Ī and D were related by the simple additive case of the exponential map). But via Herschel he was
influenced by Arbogast's ideas in the matter of iteration, i.e. composing a function
with itself, possibly many times. Writing in a major paper on
functional equations in the Philosophical
Transactions (1815/6), Babbage said his starting point was
work of Gaspard Monge.
Academic
From 1828 to 1839 Babbage was Lucasian Professor of
Mathematics at Cambridge. Not a conventional resident don, and inattentive to teaching, he wrote three
topical books during this period of his life. He was elected a Foreign Honorary
Member of the American Academy of Arts and Sciences in 1832.
Babbage was out of sympathy with colleagues: George
Biddell Airy,
his predecessor there, thought an issue should be made of his lack of interest
in lecturing. Babbage planned to lecture in 1831 on political economy. Babbage's reforming
direction looked to see university education more inclusive, universities doing
more for research, a broader syllabus and more interest in applications; but William Whewell found the programme
unacceptable. A controversy Babbage had with Richard
Jones lasted for six years. He never did give a
lecture.
It was during this period that Babbage tried
to enter politics. Simon Schaffer writes that his views of
the 1830s included disestablishment of the Church of England, a broader political
franchise,
and inclusion of manufacturers as stakeholders. He twice stood for
Parliament as a candidate for the borough of Finsbury.
In 1832 he came in third among five candidates, missing out by some 500 votes
in the two-member constituency when two other reformist candidates, Thomas Wakley and Christopher Temple,
split the vote. In his memoirs Babbage related how this
election brought him the friendship of Samuel Rogers: his brother Henry Rogers
wished to support Babbage again, but died within days. In 1834 Babbage finished
last among four.
The "Declinarian", learned
societies and the BAAS
Babbage now emerged as a polemicist. One of
his biographers notes that all his books contain a "campaigning
element". His Reflections on the Decline of Science and
some of its Causes(1830)
stands out, however, for its sharp attacks. It aimed to improve British science,
and more particularly to oust Davies Gilbert as President of the Royal
Society, which Babbage wished to reform. It was written out of
pique, when Babbage hoped to become the junior secretary of the Royal Society,
as Herschel was the senior, but failed because of his antagonism to Humphry Davy. Michael Faraday had a reply written, by Gerrit Moll,
as On the Alleged Decline of Science in England (1831). On the front of the Royal
Society Babbage had no impact, with the bland election of the Duke of Sussex to succeed Gilbert the same
year. As a broad manifesto, on the other hand, his Decline led promptly to the
formation in 1831 of the British Association for the
Advancement of Science (BAAS).
The Mechanics' Magazine in 1831 identified as
Declinarians the followers of Babbage. In an unsympathetic tone it pointed out David Brewster writing in the Quarterly Review as another leader; with the
barb that both Babbage and Brewster had received public money.
In the debate of the period on statistics (qua data collection) and what
is now statistical
inference,
the BAAS in its Statistical Section (which owed something also to Whewell)
opted for data collection. This Section was the sixth, established in 1833 with
Babbage as chairman and John
Elliot Drinkwater as secretary. The foundation of the Statistical
Society followed. Babbage was its public
face, backed by Richard Jones and Robert Malthus.
On the Economy of Machinery and Manufactures
Babbage's notation for
machine parts, explanation from On a method of expressing by signs the action
of machinery (1827) of his "Mechanical
Notation", invented for his own use in understanding the work on the
difference engine, and an influence on the conception of the analytical engine
Babbage published On the Economy of Machinery
and Manufactures (1832), on the organisation of industrial
production. It was an influential early work of operational
research. John
Rennie the Younger in addressing the Institute
of Civil Engineers on manufacturing in 1846 mentioned mostly
surveys in encyclopedias, and Babbage's book was first an article in the EncyclopƦdia
Metropolitana, the form in which Rennie noted it, in the company of
related works by John Farey, Jr., Peter
Barlow and Andrew Ure. From An essay on the general
principles which regulate the application of machinery to manufactures and the
mechanical arts (1827), which became the EncyclopƦdia Metropolitana article of 1829, Babbage
developed the schematic classification of machines that, combined with
discussion of factories, made up the first part of the book. The second part
considered the "domestic and political economy" of manufactures.
The book sold well, and quickly went to a
fourth edition (1836). Babbage represented his work as largely a
result of actual observations in factories, British and abroad. It was not, in
its first edition, intended to address deeper questions of political economy;
the second (late 1832) did, with three further chapters including one on piece rate. The book also contained
ideas on rational design in factories, and profit sharing.
The Babbage principle
In Economy of Machinery was described what is now
called the Babbage principle. It pointed out commercial
advantages available with more carefuldivision
of labour.
As Babbage himself noted, it had already appeared in the work of Melchiorre Gioia in 1815. The term was introduced in
1974 byHarry
Braverman. Related formulations are
the "principle of multiples" of Philip
Sargant Florence,
and the "balance of processes".
What Babbage remarked is that skilled workers
typically spend parts of their time performing tasks that are below their skill
level. If the labour process can be divided among several workers, labour costs
may be cut by assigning only high-skill tasks to high-cost workers, restricting
other tasks to lower-paid workers. He pointed out also that
training or apprenticeship can be taken as fixed costs; but that returns to scale are available by his
approach of standardisation of tasks, therefore again favouring the factory system. His view of human capital was restricted to
minimising the time period for recovery of training costs.
Publishing
Another aspect of the work was its detailed
breakdown of the cost structure of book publishing. Babbage took the unpopular
line, from the publishers' perspective, of exposing the trade's profitability. He went as far as to name
the organisers of the trade's restrictive practices. Twenty years later he
attended a meeting hosted by John
Chapman to campaign against the Booksellers
Association, still a cartel.
Influence
It has been written that "what Arthur
Young was to agriculture, Charles Babbage was to
the factory visit and machinery". Babbage's theories are said
to have influenced the layout of the 1851
Great Exhibition, and his views had a strong
effect on his contemporary George
Julius Poulett Scrope. Karl Marx argued that the source of
the productivity of the factory system was
exactly the combination of the division of labour with machinery, building on Adam Smith, Babbage and Ure. Where Marx picked up on
Babbage and disagreed with Smith was on the motivation for division of labour
by the manufacturer: as Babbage did, he wrote that it was for the sake of profitability, rather than productivity,
and identified an impact on the concept of a trade. John Ruskinwent further, to oppose
completely what manufacturing in Babbage's sense stood for. Babbage also affected the
economic thinking of John Stuart Mill.
George Holyoake saw Babbage's detailed
discussion of profit sharing as substantive, in the tradition of Robert Owen and Charles Fourier, if requiring the
attentions of a benevolent captain
of industry,
and ignored at the time. The French engineer and writer on industrial
organisation LƩon Lalande was influenced by Babbage,
but also the economist Claude Lucien Bergery, in reducing the issues to
"technology". William Jevons connected Babbage's
"economy of labour" with his own labour experiments of 1870. The Babbage principle is an
inherent assumption inFrederick
Winslow Taylor's scientific
management.
Natural theology
In 1837, responding to the series of eight Bridgewater
Treatises,
Babbage published his Ninth
Bridgewater Treatise, under the title On the Power, Wisdom and
Goodness of God, as manifested in the Creation. In this work Babbage
weighed in on the side of uniformitarianism in a current debate. He preferred the conception
of creation in which natural law dominated, removing the
need for "contrivance". The book is a work of natural theology, and incorporates extracts
from related correspondence of Herschel with Charles Lyell. It was quoted extensively
in Vestiges of the Natural History of Creation.
Babbage put forward the thesis that God had
the omnipotence and foresight to create as a divine legislator. He could make
laws which then produced species at the appropriate times,
rather than continually interfering with ad hoc miracles each time a new species was
required. In Vestiges the parallel with Babbage's
computing machines is made explicit, as allowing plausibility to the theory
that transmutation
of species could be pre-programmed.
Plate from the Ninth Bridgewater Treatise, showing a parametric
family ofalgebraic
curves acquiring isolated real points
Babbage has been seen as influenced by Indian
thought, in particular Indian logic; one possible route would
be through Henry
Thomas Colebrooke.
Mary
Everest Boole claims that Babbage was introduced to Indian
thought in the 1820s by her uncle George Everest:
Some
time about 1825, [Everest] came to England for two or three years, and made a
fast and lifelong friendship with Herschel and with Babbage, who was then quite
young. I would ask any fair-minded mathematician to read Babbage's Ninth Bridgewater
Treatise and compare it with the works of his contemporaries in England; and
then ask himself whence came the peculiar conception of the nature of miracle
which underlies Babbage's ideas of Singular Points on Curves (Chap, viii) –
from European Theology or Hindu Metaphysic? Oh! how the English clergy of that
day hated Babbage's book!
Later life
The British Association was consciously
modelled on the Deutsche Naturforscher-Versammlung, founded in 1822. It rejected romantic science as well as metaphysics, and started to entrench
the divisions of science from literature, and professionals from amateurs. Belonging as he did to the
"Wattite" faction in the BAAS, represented in particular by James
Watt the younger,
Babbage identified closely with industrialists. He wanted to go faster in the
same directions, and had little time for the more gentlemanly component of its
membership. Indeed, he subscribed to a version ofconjectural
history that placed industrial
society as the culmination of human development (and
shared this view with Herschel). A clash with Roderick
Murchison led in 1838 to his withdrawal from further
involvement. At the end of the same year he sent in his
resignation as Lucasian professor, walking away also from the Cambridge
struggle with Whewell. His interests became more focussed, on computation and metrology, and on international
contacts.
Metrology programme
A project announced by Babbage was to
tabulate all physical constants (referred to as
"constants of nature", a phrase in itself a neologism), and then to
compile an encyclopedic work of numerical information. He was a pioneer in the
field of "absolute measurement". His ideas followed on from
those of Johann
Christian Poggendorff,
and were mentioned to Brewster in 1832. There were to be 19 categories of
constants, and Ian Hacking sees these as reflecting in
part Babbage's "eccentric enthusiasms". Babbage's paper On Tables of the Constants
of Nature and Art was reprinted by the Smithsonian
Institution in 1856, with an added note that the physical
tables of Arnold
Henry Guyot "will form a part of the important work
proposed in this article".
Exact measurement was also key to the
development of machine tools. Here again Babbage is considered a pioneer, with Henry Maudslay, William Sellers, and Joseph Whitworth.
Engineer and inventor
Through the Royal Society Babbage acquired
the friendship of the engineer Marc Brunel. It was through Brunel
that Babbage knew of Joseph Clement, and so came to encounter the artisans whom
he observed in his work on manufactures. Babbage provided an
introduction for Isambard Kingdom Brunel in 1830, for a contact with
the proposed Bristol & Birmingham Railway. He carried out studies,
around 1838, to show the superiority of the broad gauge for railways, used by
Brunel's Great
Western Railway.
In 1838, Babbage invented the pilot (also called a
cow-catcher), the metal frame attached to the front of locomotives that clears
the tracks of obstacles; he also constructed a dynamometer car. His eldest son, Benjamin
Herschel Babbage,
worked as an engineer for Brunel on the railways before emigrating to Australia
in the 1850s.
Babbage also invented an ophthalmoscope, which he gave to Thomas
Wharton Jones for testing. Jones, however, ignored it. The
device only came into use after being independently invented by Hermann
von Helmholtz.
Cryptography
Babbage achieved notable results in cryptography, though this was still not
known a century after his death. Letter frequency was category 18 of
Babbage's tabulation project. Joseph Henry later defended interest in
it, in the absence of the facts, as relevant to the management of movable type.
During the Crimean War of the 1850s, Babbage broke
VigenĆØre's autokey cipher as well as the much weaker cipher that is
called VigenĆØre cipher today. His discovery was kept a
military secret, and was not published. Credit for the result was instead given
to Friedrich Kasiski, a Prussian infantry
officer, who made the same discovery some years later. Babbage did write to theJournal
of the Society for Arts a short letter "Cypher Writing"
which was printed on 7 December 1855. His priority wasn't
established until 1985.
Public nuisances
Babbage involved himself in well-publicised
but unpopular campaigns against public nuisances. He once counted all the
broken panes of glass of a factory, publishing in 1857 a "Table of the
Relative Frequency of the Causes of Breakage of Plate Glass Windows": Of
464 broken panes, 14 were caused by "drunken men, women or boys".
Babbage's distaste for commoners ("the
Mob") included writing "Observations of Street Nuisances" in
1864, as well as tallying up 165 "nuisances" over a period of 80
days. He especially hatedstreet
music,
and in particular the music of organ grinders, against whom he railed in
various venues. The following quotation is typical:
It
is difficult to estimate the misery inflicted upon thousands of persons, and
the absolute pecuniary penalty imposed upon multitudes of intellectual workers
by the loss of their time, destroyed by organ-grinders and other similar
nuisances.
In the 1860s, Babbage also took up the anti-hoop-rolling campaign. He blamed
hoop-rolling boys for driving their iron hoops under horses' legs, with the
result that the rider is thrown and very often the horse breaks a leg. Babbage achieved a certain
notoriety in this matter, being denounced in debate in Commons in 1864 for
"commencing a crusade against the popular game of tip-catand the trundling of
hoops."
Death
Babbage lived and worked for over 40 years at
1 Dorset Street, Marylebone, where he died, at the age of 79, on 18 October
1871; he was buried in London'sKensal
Green Cemetery.
According to Horsley, Babbage died "of renal inadequacy, secondary to cystitis." He had declined both a
knighthood and baronetcy. He also argued against hereditary
peerages,
favoring life peerages instead.
In 1983 the autopsy report for Charles
Babbage was discovered and later published by his great-great-grandson. A copy of the original is
also available. Half of Babbage's brain is preserved at the Hunterian Museum in the Royal
College of Surgeons in London. The other half of Babbage's
brain is on display in the Science Museum, London.
Computing pioneer
Part of Babbage's
difference engine (#1), assembled after his death by Babbage's son, Henry
Prevost Babbage (1824-1918), using parts found in his laboratory
Babbage's machines were among the first
mechanical computers. That they were not actually completed was largely because
of funding problems and personality issues.
Babbage directed the building of some
steam-powered machines that achieved some modest success, suggesting that
calculations could be mechanised. For more than ten years he received government
funding for his project, which amounted to £17,000, but eventually the Treasury
lost confidence in him.
While Babbage's machines were mechanical and
unwieldy, their basic architecture was similar to a modern computer. The data
and program memory were separated, operation was instruction-based, the control
unit could make conditional jumps, and the machine had a separate I/O unit.
Background on mathematical tables
In Babbage's time, printed mathematical
tables were calculated by human computers, in other words by hand.
They were central to navigation, science and engineering, as well as
mathematics. Mistakes were known to occur in transcription as well as
calculation.
At Cambridge, Babbage saw the fallibility of
this process, and the opportunity of adding mechanisation into its management.
His own account of his path towards mechanical computation references a
particular occasion:
In
1812 he was sitting in his rooms in the Analytical Society looking at a table
of logarithms, which he knew to be full of mistakes, when the idea occurred to
him of computing all tabular functions by machinery. The French government had
produced several tables by a new method. Three or four of their mathematicians
decided how to compute the tables, half a dozen more broke down the operations
into simple stages, and the work itself, which was restricted to addition and
subtraction, was done by eighty computers who knew only these two arithmetical
processes. Here, for the first time, mass production was applied to arithmetic,
and Babbage was seized by the idea that the labours of the unskilled computers
could be taken over completely by machinery which would be quicker and more
reliable.
There was another period, seven years later,
when his interest was aroused by the issues around computation of mathematical
tables. The French official initiative by Gaspard de Prony, and its problems of implementation, were
familiar to him. After the Napoleonic Wars came to a close, scientific
contacts were renewed on the level of personal contact: in 1819 Charles Blagden was in Paris looking into
the printing of the stalled de Prony project, and lobbying for the support of
the Royal Society. In works of the 1820s and 1830s, Babbage referred in detail
to de Prony's project.
Difference engine
Babbage began in 1822 with what he called the
difference engine, made to compute values of polynomial
functions.
It was created to calculate a series of values automatically. By using the
method of finite differences, it was possible to avoid
the need for multiplication and division.
For a prototype difference engine, Babbage
brought in Joseph Clement to implement the design, in
1823. Clement worked to high standards, but hismachine tools were particularly
elaborate. Under the standard terms of business of the time, he could charge
for their construction, and would also own them. He and Babbage fell out over
costs around 1831.
Some parts of the prototype survive in the
Museum of the History of Science in Oxford. This prototype evolved into
the "first difference engine." It remained unfinished and the
finished portion is located at the Science Museum in London. This first
difference engine would have been composed of around 25,000 parts, weigh
fifteen tons (13,600 kg), and would
have been 8 ft (2.4 m) tall. Although Babbage received ample funding
for the project, it was never completed. He later designed an improved
version,"Difference Engine No. 2", which was not constructed until
1989–91, using his plans and 19th century manufacturing tolerances. It
performed its first calculation at the London Science Museum, returning results
to 31 digits.
Nine years later, the Science Museum
completed the printer Babbage had designed for
the difference engine.
Completed models
The London Science Museum has constructed two
Difference Engines according to Babbage's plans for the Difference Engine No 2.
One is owned by the museum. The other, owned by the technology multimillionaire Nathan Myhrvold, went on exhibition at the Computer
History Museum in Mountain
View, California on 10 May 2008. The two models that have
been constructed are not replicas; Myhrvold's engine is the first design by
Babbage, and the London Science Museum's is a later model.
Analytical Engine
After the attempt at making the difference
engine fell through, Babbage worked to design a more complex machine called the Analytical Engine. He hired C. G. Jarvis,
who had previously worked for Clement as a draughtsman. The Analytical Engine marks
the transition from mechanised arithmetic to fully-fledged general purpose
computation. It is largely on it that Babbage's standing as computer pioneer
rests.
The major innovation was that the Analytical
Engine was to be be programmed using punched cards: the Engine was intended
to use loops of Jacquard's punched cards to control a
mechanical calculator, which could use as input the results of preceding
computations. The machine was also intended to employ
several features subsequently used in modern computers, including sequential
control, branching and looping. It would have been the first mechanical device
to be, in principle, Turing-complete. The Engine was not a
single physical machine, but rather a succession of designs that Babbage
tinkered with until his death in 1871.
Part of the Analytical Engine
on display, in 1843, left of centre in this engraving of the King George III
Museum
Ada Lovelace and Italian followers
Babbage had no research team. Ada Lovelace corresponded with him during his development
of the Analytical Engine. She is credited with developing an algorithm for the
Analytical Engine to calculate a sequence of Bernoulli numbers. Although there is
disagreement over how much of the ideas were Lovelace's own, she is often
described as the first computer programmer. She also translated and
wrote literature supporting the project. Babbage visited Turin in 1840 at the invitation of Giovanni Plana. In 1842 Charles
Wheatstone approached Lovelace to translate a paper of Luigi Menabrea, who had taken notes of
Babbage's Turin talks; and Babbage asked her to add something of her own. Fortunato Prandi who acted as interpreter in
Turin was an Italian exile and follower of Giuseppe Mazzini.
Swedish followers
Per Georg Scheutz wrote about the difference
engine in 1830, and experimented in automated computation. After 1834 and
Lardner's Edinburgh Reviewarticle he set up a project
of his own, doubting whether Babbage's initial plan could be carried out. This
he pushed through with his son, Edvard Scheutz. Another Swedish engine was
that of Martin Wiberg (1860).
Legacy
In 2011, researchers in Britain embarked on a
multimillion-pound project, "Plan
28",
to construct Babbage's Analytical Engine. Since Babbage's plans were
continually being refined and were never completed, they will engage the public
in the project and crowd-source the analysis of what should
be built. It would have the equivalent of 675 bytes of
memory, and run at a clock speed of about 7 Hz. They hope to complete it
by the 150th anniversary of Babbage's death, in 2021.
Advances in MEMs and nanotechnology have led to recent
high-tech experiments in mechanical computation. The benefits suggested include
operation in high radiation or high temperature environments. These modern versions of
mechanical computation were highlighted in The Economist in its special "end of
the millennium" black cover issue in an article entitled "Babbage's
Last Laugh".
Family
On 25 July 1814, Babbage married Georgiana
Whitmore at St. Michael's Church in Teignmouth, Devon; her sister Louisa
married Edward Ryan. The couple lived at Dudmaston Hall,Shropshire
(where Babbage engineered the central heating system), before moving to 5
Devonshire Street, Portland Place, London.
Charles and Georgiana had eight children, but only four — Benjamin
Herschel,
Georgiana Whitmore, Dugald Bromhead and Henry Prevost —
survived childhood. Charles' wife Georgiana died in Worcester on 1 September 1827, the
same year as his father, their second son (also named Charles) and their
newborn son Alexander.
His youngest son, Henry Prevost Babbage
(1824–1918), went on to create six working difference engines based on his
father's designs, one of which was sent to Harvard
University where it was later discovered by Howard H. Aiken, pioneer of the Harvard Mark I. Henry Prevost's 1910
Analytical Engine Mill, previously on display at Dudmaston Hall, is now on display at the Science
Museum.
Memorials
There is a green plaque commemorating the 40 years
Babbage spent at 1 Dorset St, London. Locations, institutions and
other things named after Babbage include:
·
The Charles
Babbage Institute,
an information technology archive and research center at the University
of Minnesota
·
The
Babbage Building at the University
of Plymouth,
where the university's school of computing is based
In fiction and film
Babbage frequently appears in steampunk works; he has been called
an iconic figure of the genre. Other works in which
Babbage appears include:
Publications
·
Babbage, Charles (1826). A
Comparative View of the Various Institutions for the Assurance of Lives.
London: J. Mawman.
·
Babbage, Charles (1830). Reflections
on the Decline of Science in England, and on Some of Its Causes.
London: B. Fellowes.
·
Babbage, Charles (1835). On
the Economy of Machinery and Manufactures (4 ed.). London:
Charles Knight.
·
Babbage, Charles (1837). The
Ninth Bridgewater Treatise, a Fragment. London: John
Murray. (reissued
by Cambridge University Press 2009,ISBN
978-1-108-00000-0)
·
Babbage, Charles (1841). Table
of the Logarithms of the Natural Numbers from 1 to 108000.
London: William Clowes and Sons. (theLOCOMAT site contains a
reconstruction of this table)
·
Babbage, Charles (1989). In Hyman,
Anthony. Science
and Reform: Selected Works of Charles Babbage.
Cambridge University Press. ISBN 978-0-521-34311-4.
References
·
Alex
D. D. Craik, Prehistory of FaĆ di Bruno's Formula, The American Mathematical
Monthly Vol. 112, No. 2 (Feb., 2005), pp. 119-130. Published by: Mathematical
Association of America.Stable URL: http://www.jstor.org/stable/30037410









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