to+produce+evidence

Burgi, Jost

SUBJECT AREA: Horology

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b. 28 February 1552 Lichtensteig, Switzerland

d. 31 January 1632 Kassel, Germany

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Swiss clockmaker and mathematician who invented the remontoire and the cross-beat escapement, also responsible for the use of exponential notation and the calculation of tables of anti-logarithms.

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Burgi entered the service of Duke William IV of Hesse in 1579 as Court Clockmaker, although he also assisted William with his astronomical observations. In 1584 he invented the cross-beat escapement which increased the accuracy of spring-driven clocks by two orders of magnitude. During the last years of the century he also worked on the development of geometrical and astronomical instruments for the Royal Observatory at Kassel.

On the death of Duke Wilhelm in 1603, and with news of his skills having reached the Holy Roman Emperor Rudolph II, in 1604 he went to Prague to become Imperial Watchmaker and to assist in the creation of a centre of scientific activity, subsequently becoming Assistant to the German astronomer, Johannes Kepler. No doubt this association led to an interest in mathematics and he made significant contributions to the concept of decimal fractions and the use of exponential notation, i.e. the use of a raised number to indicate powers of another number. It is likely that he was developing the idea of logarithms at the same time (or possibly even before) Napier, for in 1620 he made his greatest contribution to mathematics, science and, eventually, engineering, namely the publication of tables of anti-logarithms.

At Prague he continued the series of accurate clocks and instruments for astronomical measurements that he had begun to produce at Kassel. At that period clocks were very poor timekeepers since the controller, the foliot or balance, had no natural period of oscillation and was consequently dependent on the driving force. Although the force of the driving weight was constant, irregularities occurred during the transmission of the power through the train as a result of the poor shape and quality of the gearing. Burgi attempted to overcome this directly by superb craftsmanship and indirectly by using a remontoire. This device was wound at regular intervals by the main driving force and fed the power directly to the escape wheel, which impulsed the foliot. He also introduced the crossbeat escapement (a variation on the verge), which consisted of two coupled foliots that swung in opposition to each other. According to contemporary evidence his clocks produced a remarkable improvement in timekeeping, being accurate to within a minute a day. This improvement was probably a result of the use of a remontoire and the high quality of the workmanship rather than a result of the cross-beat escapement, which did not have a natural period of oscillation.

Burgi or Prague clocks, as they were known, were produced by very few other makers and were supplanted shortly afterwards by the intro-duction of the pendulum clock. Burgi also produced superb clockwork-driven celestial globes.

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Principal Honours and Distinctions

Ennobled 1611.

Bibliography

Burgi only published one book, and that was concerned with mathematics.

Further Reading

L.von Mackensen, 1979, Die erste Sternwarte Europas mit ihren Instrumenten and Uhren—400 Jahre Jost Burgi in Kassel, Munich.

K.Maurice and O.Mayr (eds), 1980, The Clockwork Universe, Washington, DC, pp. 87– 102.

H.A.Lloyd, 1958, Some Outstanding Clocks Over 700 Years, 1250–1950, London. E.T.Bell, 1937, Men of Mathematics, London: Victor Gollancz.

See also: Briggs, Henry

KF / DV

Crompton, Samuel

SUBJECT AREA: Textiles

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b. 3 December 1753 Firwood, near Bolton, Lancashire, England

d. 26 June 1827 Bolton, Lancashire, England

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English inventor of the spinning mule.

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Samuel Crompton was the son of a tenant farmer, George, who became the caretaker of the old house Hall-i-th-Wood, near Bolton, where he died in 1759. As a boy, Samuel helped his widowed mother in various tasks at home, including weaving. He liked music and made his own violin, with which he later was to earn some money to pay for tools for building his spinning mule. He was set to work at spinning and so in 1769 became familiar with the spinning jenny designed by James Hargreaves; he soon noticed the poor quality of the yarn produced and its tendency to break. Crompton became so exasperated with the jenny that in 1772 he decided to improve it. After seven years' work, in 1779 he produced his famous spinning "mule". He built the first one entirely by himself, principally from wood. He adapted rollers similar to those already patented by Arkwright for drawing out the cotton rovings, but it seems that he did not know of Arkwright's invention. The rollers were placed at the back of the mule and paid out the fibres to the spindles, which were mounted on a moving carriage that was drawn away from the rollers as the yarn was paid out. The spindles were rotated to put in twist. At the end of the draw, or shortly before, the rollers were stopped but the spindles continued to rotate. This not only twisted the yarn further, but slightly stretched it and so helped to even out any irregularities; it was this feature that gave the mule yarn extra quality. Then, after the spindles had been turned backwards to unwind the yarn from their tips, they were rotated in the spinning direction again and the yarn was wound on as the carriage was pushed up to the rollers.

The mule was a very versatile machine, making it possible to spin almost every type of yarn. In fact, Samuel Crompton was soon producing yarn of a much finer quality than had ever been spun in Bolton, and people attempted to break into Hall-i-th-Wood to see how he produced it. Crompton did not patent his invention, perhaps because it consisted basically of the essential features of the earlier machines of Hargreaves and Arkwright, or perhaps through lack of funds. Under promise of a generous subscription, he disclosed his invention to the spinning industry, but was shabbily treated because most of the promised money was never paid. Crompton's first mule had forty-eight spindles, but it did not long remain in its original form for many people started to make improvements to it. The mule soon became more popular than Arkwright's waterframe because it could spin such fine yarn, which enabled weavers to produce the best muslin cloth, rivalling that woven in India and leading to an enormous expansion in the British cotton-textile industry. Crompton eventually saved enough capital to set up as a manufacturer himself and around 1784 he experimented with an improved carding engine, although he was not successful. In 1800, local manufacturers raised a sum of £500 for him, and eventually in 1812 he received a government grant of £5,000, but this was trifling in relation to the immense financial benefits his invention had conferred on the industry, to say nothing of his expenses. When Crompton was seeking evidence in 1811 to support his claim for financial assistance, he found that there were 4,209,570 mule spindles compared with 155,880 jenny and 310,516 waterframe spindles. He later set up as a bleacher and again as a cotton manufacturer, but only the gift of a small annuity by his friends saved him from dying in total poverty.

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Further Reading

H.C.Cameron, 1951, Samuel Crompton, Inventor of the Spinning Mule, London (a rather discursive biography).

Dobson \& Barlow Ltd, 1927, Samuel Crompton, the Inventor of the Spinning Mule, Bolton.

G.J.French, 1859, The Life and Times of Samuel Crompton, Inventor of the Spinning Machine Called the Mule, London.

The invention of the mule is fully described in H. Gatling, 1970, The Spinning Mule, Newton Abbot; W.English, 1969, The Textile Industry, London; R.L.Hills, 1970, Power in the Industrial Revolution, Manchester.

C.Singer (ed.), 1958, A History of Technology, Vol. IV, Oxford: Clarendon Press (provides a brief account).

RLH

Gurney, Sir Goldsworthy

SUBJECT AREA: Automotive engineering, Land transport, Mining and extraction technology, Steam and internal combustion engines

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b. 14 February 1793 Treator, near Padstow, Cornwall, England

d. 28 February 1875 Reeds, near Bude, Cornwall, England

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English pioneer of steam road transport.

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Educated at Truro Grammar School, he then studied under Dr Avery at Wadebridge to become a doctor of medicine. He settled as a surgeon in Wadebridge, spending his leisure time in building an organ and in the study of chemistry and mechanical science. He married Elizabeth Symons in 1814, and in 1820 moved with his wife to London. He delivered a course of lectures at the Surrey Institution on the elements of chemical science, attended by, amongst others, the young Michael Faraday. While there, Gurney made his first invention, the oxyhydrogen blowpipe. For this he received the Gold Medal of the Society of Arts. He experimented with lime and magnesia for the production of an illuminant for lighthouses with some success. He invented a musical instrument of glasses played like a piano.

In 1823 he started experiments related to steam and locomotion which necessitated taking a partner in to his medical practice, from which he resigned shortly after. His objective was to produce a steam-driven vehicle to run on common roads. His invention of the steam-jet of blast greatly improved the performance of the steam engine. In 1827 he took his steam carriage to Cyfarthfa at the request of Mr Crawshaw, and while there applied his steam-jet to the blast furnaces, greatly improving their performance in the manufacture of iron. Much of the success of George Stephenson's steam engine, the Rocket was due to Gurney's steam blast.

In July 1829 Gurney made a historic trip with his road locomotive. This was from London to Bath and back, which was accomplished at a speed of 18 mph (29 km/h) and was made at the instigation of the Quartermaster-General of the Army. So successful was the carriage that Sir Charles Dance started to run a regular service with it between Gloucester and Cheltenham. This ran for three months without accident, until Parliament introduced prohibitive taxation on all self-propelled vehicles. A House of Commons committee proposed that these should be abolished as inhibiting progress, but this was not done. Sir Goldsworthy petitioned Parliament on the harm being done to him, but nothing was done and the coming of the railways put the matter beyond consideration. He devoted his time to finding other uses for the steam-jet: it was used for extinguishing fires in coal-mines, some of which had been burning for many years; he developed a stove for the production of gas from oil and other fatty substances, intended for lighthouses; he was responsible for the heating and the lighting of both the old and the new Houses of Parliament. His evidence after a colliery explosion resulted in an Act of Parliament requiring all mines to have two shafts. He was knighted in 1863, the same year that he suffered a stroke which incapacitated him. He retired to his house at Reeds, near Bude, where he was looked after by his daughter, Anna.

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Principal Honours and Distinctions

Knighted 1863. Society of Arts Gold Medal.

IMcN

Ravenscroft, George

SUBJECT AREA: Chemical technology, Photography, film and optics

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b. 1632 Alconbury, Huntingdonshire, England

d. 7 June 1683 Barnet, Hertfordshire, England

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English inventor of lead-crystal glass.

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George's father James was a successful lawyer and merchant, engaging in overseas trade.

A devout but necessarily circumspect Catholic, James sent his sons to the English College at Douai, now in northern France. Leaving there in 1651, George began to learn his father's business and spent some fifteen years in Venice. He took an increasingly important part in it, doubtless dealing in Venice's leading products of lace and glass. By 1666 he was back in England and, perhaps because the supply of Venetian glass was beginning to decline, he started to manufacture glass himself. In 1673 he set up a glassworks in the Savoy in London and succeeded so well that in the following year he petitioned the King for the grant of a patent to make glassware. This was granted on 16 May 1674, stimulating the Glass Sellers' Company to enter into an agreement with Ravenscroft to buy the glassware he produced. Later in 1674 the company allowed Ravenscroft to establish a second glasshouse at Henley-onThames. At first his ware was beset with "crizzling", i.e. numerous fine surface cracks. The Glass Sellers probably urged Ravenscroft to cure this defect, and this he achieved in 1675 by replacing crushed flint with increasing amounts of lead oxide, rising finally to a content of 30 per cent. He thereby obtained a relatively soft, heavy glass with high refractive index and dispersive power. This made it amenable to deep cutting, to produce the brilliant prismatic effects of cut glass. At about the same time, the Duke of Buckingham, a considerable promoter of the glass industry, agreed that Ravenscroft should manage his works at Vauxhall for the making of plate glass for mirrors. Ravenscroft terminated his agreement with the Glass Sellers in 1678, the date of the last evidence of his activities as a maker of crystal glass, and the patent expired in 1681. His new glass had immediately rivalled the best Venetian crystal glass and has been a valued product ever since.

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Further Reading

R.F.Moody, 1988, The life of George Ravenscroft', Glass Technology 29 (1):198–210;

Glass Technology 30(5):191–2 (additional notes on his life).

LRD

proof

[pru:f]

proof установленный градус крепости спирта; above (under) proof выше (ниже) установленного градуса absolute proof определенное доказательство constructive proof конструктивное доказательство correctness proof доказательство правильности fictitious proof ложное доказательство final burden of proof окончательная обязанность доказывания final burden of proof окончательное бремя доказывания further proof дополнительное доказательство page proof полигр. корректурный оттиск со сверстанного набора page proof страничная корректура press proof полигр. сводка prima facie proof доказательство, достаточное при отсутствии опровержения produce proof предъявлять доказательство program proof вчт. доказательство правильности программы proof делать непроницаемым proof в сложных словах означает устойчивый, непроницаемый, не поддающийся действию (чего-л.); waterproof водонепроницаемый proof делать пробный оттиск proof доказательство; this requires no proof это не требует доказательства proof доказательство proof доказывание proof испытание; проба; to put (smth.) to the proof испытать (что-л.), подвергнуть (что-л.) испытанию proof испытание proof корректура; гранка; пробный оттиск (с гравюры) proof корректура proof недоступный, не поддающийся (лести и т. п.) proof недоступный proof непробиваемый proof непроницаемый (against); непробиваемый proof непроницаемый proof придавать непроницаемость proof проба proof пробирка proof пробный оттиск proof проверка proof мат. проверка proof (шотл.) рассмотрение дела судьей вместо суда присяжных proof свидетельское показание proof установленной крепости (о спирте) proof установленный градус крепости спирта; above (under) proof выше (ниже) установленного градуса proof by appearance доказательство, достаточное при отсутствии опровержения proof by appearance презумпция доказательства proof in slips полигр. корректура в гранках proof of debt банкрот. подтверждение доказательством заявления кредитора proof of evidence свидетельское показание proof of good character and repute рекомендательное письмо proof of identity доказательство подлинности proof of membership членский билет proof of nonnegligent behaviour доказательство отсутствия небрежности proof of paternity доказательство отцовства proof of posting контроль проводки proof of purchase доказательство покупки proof of service доказательство оказания услуги proof of termination вчт. доказательство правильности завершения работы proof of will доказывание завещания proof испытание; проба; to put (smth.) to the proof испытать (что-л.), подвергнуть (что-л.) испытанию reproduction proof полигр. оттиск с набора, предназначенного для фоторепродуцирования specimen proof print. пробный оттиск proof доказательство; this requires no proof это не требует доказательства proof в сложных словах означает устойчивый, непроницаемый, не поддающийся действию (чего-л.); waterproof водонепроницаемый water-repellent: water-repellent = waterproof waterproof: waterproof водонепроницаемый, непромокаемый proof непромокаемый плащ proof придавать водонепроницаемость written proof письменное доказательство

Memory

   1) A Unitary Search Process for All the Phenomena of Memory

   To what extent can we lump together what goes on when you try to recall: (1) your name; (2) how you kick a football; and (3) the present location of your car keys? If we use introspective evidence as a guide, the first seems an immediate automatic response. The second may require constructive internal replay prior to our being able to produce a verbal description. The third... quite likely involves complex operational responses under the control of some general strategy system. Is any unitary search process, with a single set of characteristics and inputoutput relations, likely to cover all these cases? (Reitman, 1970, p. 485)

   2) Semantic Memory Is a Mental Thesaurus

   [Semantic memory] Is a mental thesaurus, organized knowledge a person possesses about words and other verbal symbols, their meanings and referents, about relations among them, and about rules, formulas, and algorithms for the manipulation of these symbols, concepts, and relations. Semantic memory does not register perceptible properties of inputs, but rather cognitive referents of input signals. (Tulving, 1972, p. 386)

   3) The Development of Mnemonic Codes

   The mnemonic code, far from being fixed and unchangeable, is structured and restructured along with general development. Such a restructuring of the code takes place in close dependence on the schemes of intelligence. The clearest indication of this is the observation of different types of memory organisation in accordance with the age level of a child so that a longer interval of retention without any new presentation, far from causing a deterioration of memory, may actually improve it. (Piaget & Inhelder, 1973, p. 36)

   4) The Logic of Some Memory Theorization Is of Dubious Worth in the History of Psychology

   If a cue was effective in memory retrieval, then one could infer it was encoded; if a cue was not effective, then it was not encoded. The logic of this theorization is "heads I win, tails you lose" and is of dubious worth in the history of psychology. We might ask how long scientists will puzzle over questions with no answers. (Solso, 1974, p. 28)

   5) The Constituent Elements of Memory Theory

   We have iconic, echoic, active, working, acoustic, articulatory, primary, secondary, episodic, semantic, short-term, intermediate-term, and longterm memories, and these memories contain tags, traces, images, attributes, markers, concepts, cognitive maps, natural-language mediators, kernel sentences, relational rules, nodes, associations, propositions, higher-order memory units, and features. (Eysenck, 1977, p. 4)

   6) The Problem with the Memory Metaphor

   The problem with the memory metaphor is that storage and retrieval of traces only deals [ sic] with old, previously articulated information. Memory traces can perhaps provide a basis for dealing with the "sameness" of the present experience with previous experiences, but the memory metaphor has no mechanisms for dealing with novel information. (Bransford, McCarrell, Franks & Nitsch, 1977, p. 434)

   7) The Results of a Hundred Years of the Psychological Study of Memory Are Somewhat Discouraging

   The results of a hundred years of the psychological study of memory are somewhat discouraging. We have established firm empirical generalisations, but most of them are so obvious that every ten-year-old knows them anyway. We have made discoveries, but they are only marginally about memory; in many cases we don't know what to do with them, and wear them out with endless experimental variations. We have an intellectually impressive group of theories, but history offers little confidence that they will provide any meaningful insight into natural behavior. (Neisser, 1978, pp. 12-13)

   8) The Structure and Function of a Schema in Memory

   A schema, then is a data structure for representing the generic concepts stored in memory. There are schemata representing our knowledge about all concepts; those underlying objects, situations, events, sequences of events, actions and sequences of actions. A schema contains, as part of its specification, the network of interrelations that is believed to normally hold among the constituents of the concept in question. A schema theory embodies a prototype theory of meaning. That is, inasmuch as a schema underlying a concept stored in memory corresponds to the mean ing of that concept, meanings are encoded in terms of the typical or normal situations or events that instantiate that concept. (Rumelhart, 1980, p. 34)

   9) Competence and Performance in Theories of Memory

   Memory appears to be constrained by a structure, a "syntax," perhaps at quite a low level, but it is free to be variable, deviant, even erratic at a higher level....

   Like the information system of language, memory can be explained in part by the abstract rules which underlie it, but only in part. The rules provide a basic competence, but they do not fully determine performance. (Campbell, 1982, pp. 228, 229)

    10) Metaphors of Memory

   When people think about the mind, they often liken it to a physical space, with memories and ideas as objects contained within that space. Thus, we speak of ideas being in the dark corners or dim recesses of our minds, and of holding ideas in mind. Ideas may be in the front or back of our minds, or they may be difficult to grasp. With respect to the processes involved in memory, we talk about storing memories, of searching or looking for lost memories, and sometimes of finding them. An examination of common parlance, therefore, suggests that there is general adherence to what might be called the spatial metaphor. The basic assumptions of this metaphor are that memories are treated as objects stored in specific locations within the mind, and the retrieval process involves a search through the mind in order to find specific memories....

   However, while the spatial metaphor has shown extraordinary longevity, there have been some interesting changes over time in the precise form of analogy used. In particular, technological advances have influenced theoretical conceptualisations.... The original Greek analogies were based on wax tablets and aviaries; these were superseded by analogies involving switchboards, gramophones, tape recorders, libraries, conveyor belts, and underground maps. Most recently, the workings of human memory have been compared to computer functioning... and it has been suggested that the various memory stores found in computers have their counterparts in the human memory system. (Eysenck, 1984, pp. 79-80)

    11) Comparison of Primary Memory and Secondary Memory

   Primary memory [as proposed by William James] relates to information that remains in consciousness after it has been perceived, and thus forms part of the psychological present, whereas secondary memory contains information about events that have left consciousness, and are therefore part of the psychological past. (Eysenck, 1984, p. 86)

    12) Semantic Memory and Episodic Memory

   Once psychologists began to study long-term memory per se, they realized it may be divided into two main categories.... Semantic memories have to do with our general knowledge about the working of the world. We know what cars do, what stoves do, what the laws of gravity are, and so on. Episodic memories are largely events that took place at a time and place in our personal history. Remembering specific events about our own actions, about our family, and about our individual past falls into this category. With amnesia or in aging, what dims... is our personal episodic memories, save for those that are especially dear or painful to us. Our knowledge of how the world works remains pretty much intact. (Gazzaniga, 1988, p. 42)

    13) The Relation of Memory to Thinking

   The nature of memory... provides a natural starting point for an analysis of thinking. Memory is the repository of many of the beliefs and representations that enter into thinking, and the retrievability of these representations can limit the quality of our thought. (Smith, 1990, p. 1)

stressometer system

1. измеритель механических напряжений

 

измеритель механических напряжений
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[Интент]

Параллельные тексты EN-RU из ABB Review. Перевод компании Интент

High precision in Venice

From the 13th century, Venice traded in copper and bronze, which was used to manufacture coins and building details. Today, ILNOR SpA, a family-owned business established in 1961, continues the tradition of processing metals for use in various industries. The high-quality brass, bronze and copper strips it produces are used for products in the automotive, electric and electronic industries. However, the taste for aesthetical and high-quality products is centuries old in Venice, and ILNOR continues to uphold this tradition by constantly investing in technology that improves the quality of its products 1. The choice of the Stressometer 7.0 FSA from ABB was natural. Stressometer systems provide the advanced automated control system needed to produce the high-quality flat strip demanded by producers, and is evidence of ABB’s dedication to detail and perfection, something that is well recognized and appreciated in this part of the old world.

Высокая точность в Венеции

С XIII века  Венеция торгует медью и бронзой, из которых изготавливаются монеты и элементы зданий. Сегодня ILNOR SpA, семейное предприятие, основанное в 1961 году, продолжает традиции обработки металлов, которые применяются в различных отраслях промышленности. Выпускаемые им высококачественные латунные, бронзовые и медные листы используются предприятиями автомобильной, электрической и электронной промышленности. Вкус к эстетически выдержанным и высококачественным изделиям складывался в Венеции в течение многих столетий, и ILNOR продолжает эти традиции, постоянно вкладывая средства в технологии, повышающие качество изделий (рис. 1). Поэтому совершенно естественным выглядит выбор измерителя механических напряжений Stressometer 7.0 FSA компании АББ. Данные измерители механических напряжений позволяют создавать усовершенствованные системы автоматического контроля, необходимые для производства высококачественных листовых материалов, и красноречиво демонстрируют стремление компании АББ к точности и совершенству, что высоко ценится в этой части Старого Света.

EN

• stressometer system