ciphers

clavis

n книжн. ключ

clavis to ciphers — ключ к шифру

estimates

оценивает

Синонимический ряд:

1. judgements (noun) appraisals; approximations; assessments; estimations; evaluations; judgements; judgments; stocks; valuations

2. approximates (verb) approximates; calls; judges; places; puts; sets

3. calculates (verb) calculates; ciphers; computes; figures; reckons

4. rates (verb) appraises; assays; assesses; evaluates; gauges; rates; sets at; surveys; valuates; values

zeroes

нуль

leading zeroes — начальные нули

trailing zeroes — конечные нули

Синонимический ряд:

nothings (noun) ciphers; nobodies; nonentities; nothings

zeros

нуль

fill with zeros — заполнять нулями

distribution of zeros — распределение нулей

suppress zeros — подавлять нули; устранять нули

Синонимический ряд:

nonentities (noun) ciphers; goose eggs; insignificancies; nobodies; nonentities; nothings; nullities; whiffets; whippersnappers

cipher

cipher ['saɪfə(r)]

1 noun

(a) (code) chiffre m, code m secret;

∎ written in cipher crypté, codé

(b) (monogram) chiffre m, monogramme m

(c) (Arabic numeral) chiffre m

(d) literary (zero) zéro m;

∎ figurative they're mere ciphers ce sont des moins que rien

2 transitive verb

(a) (encode) crypter, chiffrer, coder

(b) (calculate) chiffrer

Morland, Sir Samuel

SUBJECT AREA: Mechanical, pneumatic and hydraulic engineering

[br]

b. 1625 Sulhampton, near Reading, Berkshire, England

d. 26 December 1695 Hammersmith, near London, England

[br]

English mathematician and inventor.

[br]

Morland was one of several sons of the Revd Thomas Morland and was probably initially educated by his father. He went to Winchester School from 1639 to 1644 and then to Magdalene College, Cambridge, where he graduated BA in 1648 and MA in 1652. He was appointed a tutor there in 1650. In 1653 he went to Sweden in the ambassadorial staff of Bulstrode Whitelocke and remained there until 1654. In that year he was appointed Clerk to Mr Secretary Thurloe, and in 1655 he was accredited by Oliver Cromwell to the Duke of Savoy to appeal for the Waldenses. In 1657 he married Susanne de Milleville of Boissy, France, with whom he had three children. In 1660 he went over to the Royalists, meeting King Charles at Breda, Holland. On 20 May, the King knighted him, creating him baron, for revealing a conspiracy against the king's life. He was also granted a pension of£500 per year. In 1661, at the age of 36, he decided to devote himself to mathematics and invention. He devised a mechanical calculator, probably based on the pattern of Blaise Pascal, for adding and subtracting: this was followed in 1666 by one for multiplying and other functions. A Perpetual Calendar or Almanack followed; he toyed with the idea of a "gunpowder engine" for raising water; he developed a range of speaking trum-pets, said to have a range of 1/2 to 1 mile (0.8–1.6 km) or more; also iron stoves for use on board ships, and improvements to barometers.

By 1675 he had started selling a range of pumps for private houses, for mines or deep wells, for ships, for emptying ponds or draining low ground as well as to quench fire or wet the sails of ships. The pumps cost from £5 to £63, and the great novelty was that he used, instead of packing around the cylinder sealing against the bore of the cylinder, a neck-gland or seal around the outside diameter of the piston or piston-rod. This revolutionary step avoided the necessity of accurately boring the cylinder, replacing it with the need to machine accurately the outside diameter of the piston or rod, a much easier operation. Twenty-seven variations of size and materials were included in his schedule of'Pumps or Water Engines of Isaac Thompson of Great Russel Street', the maker of Morland's design. In 1681 the King made him "Magister mechanicorum", or Master of Machines. In that year he sailed for France to advise Louis XIV on the waterworks being built at Marly to supply the Palace of Versailles. About this time he had shown King Charles plans for a pumping engine "worked by fire alone". He petitioned for a patent for this, but did not pursue the matter.

In 1692 he went blind. In all, he married five times. While working for Cromwell he became an expert in ciphers, in opening sealed letters and in their rapid copying.

[br]

Principal Honours and Distinctions

Knighted 1660.

Bibliography

1685, Elevation des eaux.

Further Reading

H.W.Dickinson, 1970, Sir Samuel Morland: Diplomat and Inventor, Cambridge: Newcomen Society/Heffers.

IMcN

Shannon, Claude Elwood

SUBJECT AREA: Electronics and information technology, Telecommunications

[br]

b. 30 April 1916 Gaylord, Michigan, USA

[br]

American mathematician, creator of information theory.

[br]

As a child, Shannon tinkered with radio kits and enjoyed solving puzzles, particularly crypto-graphic ones. He graduated from the University of Michigan in 1936 with a Bachelor of Science in mathematics and electrical engineering, and earned his Master's degree from the Massachusetts Institute of Technology (MIT) in 1937. His thesis on applying Boolean algebra to switching circuits has since been acclaimed as possibly the most significant this century. Shannon earned his PhD in mathematics from MIT in 1940 with a dissertation on the mathematics of genetic transmission.

Shannon spent a year at the Institute for Advanced Study in Princeton, then in 1941 joined Bell Telephone Laboratories, where he began studying the relative efficiency of alternative transmission systems. Work on digital encryption systems during the Second World War led him to think that just as ciphers hide information from the enemy, "encoding" information could also protect it from noise. About 1948, he decided that the amount of information was best expressed quantitatively in a two-value number system, using only the digits 0 and 1. John Tukey, a Princeton colleague, named these units "binary digits" (or, for short, "bits"). Almost all digital computers and communications systems use such on-off, or two-state logic as their basis of operation.

Also in the 1940s, building on the work of H. Nyquist and R.V.L. Hartley, Shannon proved that there was an upper limit to the amount of information that could be transmitted through a communications channel in a unit of time, which could be approached but never reached because real transmissions are subject to interference (noise). This was the beginning of information theory, which has been used by others in attempts to quantify many sciences and technologies, as well as subjects in the humanities, but with mixed results. Before 1970, when integrated circuits were developed, Shannon's theory was not the preferred circuit-and-transmission design tool it has since become.

Shannon was also a pioneer in the field of artificial intelligence, claiming that computing machines could be used to manipulate symbols as well as do calculations. His 1953 paper on computers and automata proposed that digital computers were capable of tasks then thought exclusively the province of living organisms. In 1956 he left Bell Laboratories to join the MIT faculty as Professor of Communications Science.

On the lighter side, Shannon has built many devices that play games, and in particular has made a scientific study of juggling.

[br]

Principal Honours and Distinctions

National Medal of Science. Institute of Electrical and Electronics Engineers Medal of Honor, Kyoto Prize.

Bibliography

His seminal paper (on what has subsequently become known as information theory) was entitled "The mathematical theory of communications", first published in Bell System Technical Journal in 1948; it is also available in a monograph (written with Warren Weaver) published by the University of Illinois Press in 1949, and in Key Papers in the Development of Information Theory, ed. David Slepian, IEEE Press, 1974, 1988. For readers who want all of Shannon's works, see N.J.A.Sloane and A.D.Wyner, 1992, The

Collected Papers of Claude E.Shannon.

HO