providing signals

providing signals

Телекоммуникации: обеспечение связи, обеспечивающий связь

providing signals

1. обеспечение связи

2. обеспечивающий связь

providing

n обеспечение

providing signals — обеспечение связи

providing system — система обеспечения

nitrogen providing — обеспечение азотом

providing for supply — обеспечение поставок

compressed gases providing — обеспечение сжатыми газами

Синонимический ряд:

1. provision (noun) contributing; equipping; furnishing; outfitting; procurement; provision; replenishment; stocking; supplying

2. giving (verb) delivering; dishing out; dispensing; feeding; finding; furnishing; giving; hand over; handing; handing over; supplying; transferring; turn over; turning over

3. offering (verb) affording; offering

4. on condition that (other) if; in case that; in the event that; just in case; on condition; on condition that; provided; subject to; supposing

providing

1. обеспечение

providing signals — обеспечение связи

providing system — система обеспечения

nitrogen providing — обеспечение азотом

providing for supply — обеспечение поставок

compressed gases providing — обеспечение сжатыми газами

2. снабжающий

providing

обеспечивающий; обеспечение

providing signals — обеспечение связи

providing system — система обеспечения

nitrogen providing — обеспечение азотом

providing for supply — обеспечение поставок

compressed gases providing — обеспечение сжатыми газами

compressed gases providing

обеспечение сжатыми газами

providing signals — обеспечение связи

providing system — система обеспечения

nitrogen providing — обеспечение азотом

providing for supply — обеспечение поставок

nitrogen providing

обеспечение азотом

providing signals — обеспечение связи

providing system — система обеспечения

providing for supply — обеспечение поставок

compressed gases providing — обеспечение сжатыми газами

an interesting direction is the utilization of single molecules, supramolecular systems, clusters and biostructures for the processing of electrical, optical, magnetic and chemical signals, providing the basis for molecular electronics

Общая лексика: интересным на

interesting direction is the utilization of single molecules, supramolecular systems, clusters and biostructures for the processing of electrical, optical, magnetic and chemical signals, providing the basis for molecular electronics

Общая лексика: интересным напра

Bain, Alexander

SUBJECT AREA: Horology, Telecommunications

[br]

b. October 1810 Watten, Scotland

d. 2 January 1877 Kirkintilloch, Scotland

[br]

Scottish inventor and entrepreneur who laid the foundations of electrical horology and designed an electromagnetic means of transmitting images (facsimile).

[br]

Alexander Bain was born into a crofting family in a remote part of Scotland. He was apprenticed to a watchmaker in Wick and during that time he was strongly influenced by a lecture on "Heat, sound and electricity" that he heard in nearby Thurso. This lecture induced him to take up a position in Clerkenwell in London, working as a journeyman clockmaker, where he was able to further his knowledge of electricity by attending lectures at the Adelaide Gallery and the Polytechnic Institution. His thoughts naturally turned to the application of electricity to clockmaking, and despite a bitter dispute with Charles Wheatstone over priority he was granted the first British patent for an electric clock. This patent, taken out on 11 January 1841, described a mechanism for an electric clock, in which an oscillating component of the clock operated a mechanical switch that initiated an electromagnetic pulse to maintain the regular, periodic motion. This principle was used in his master clock, produced in 1845. On 12 December of the same year, he patented a means of using electricity to control the operation of steam railway engines via a steam-valve. His earliest patent was particularly far-sighted and anticipated most of the developments in electrical horology that occurred during the nineteenth century. He proposed the use of electricity not only to drive clocks but also to distribute time over a distance by correcting the hands of mechanical clocks, synchronizing pendulums and using slave dials (here he was anticipated by Steinheil). However, he was less successful in putting these ideas into practice, and his electric clocks proved to be unreliable. Early electric clocks had two weaknesses: the battery; and the switching mechanism that fed the current to the electromagnets. Bain's earth battery, patented in 1843, overcame the first defect by providing a reasonably constant current to drive his clocks, but unlike Hipp he failed to produce a reliable switch.

The application of Bain's numerous patents for electric telegraphy was more successful, and he derived most of his income from these. They included a patent of 12 December 1843 for a form of fax machine, a chemical telegraph that could be used for the transmission of text and of images (facsimile). At the receiver, signals were passed through a moving band of paper impregnated with a solution of ammonium nitrate and potassium ferrocyanide. For text, Morse code signals were used, and because the system could respond to signals faster than those generated by hand, perforated paper tape was used to transmit the messages; in a trial between Paris and Lille, 282 words were transmitted in less than one minute. In 1865 the Abbé Caselli, a French engineer, introduced a commercial fax service between Paris and Lyons, based on Bain's device. Bain also used the idea of perforated tape to operate musical wind instruments automatically. Bain squandered a great deal of money on litigation, initially with Wheatstone and then with Morse in the USA. Although his inventions were acknowledged, Bain appears to have received no honours, but when towards the end of his life he fell upon hard times, influential persons in 1873 secured for him a Civil List Pension of £80 per annum and the Royal Society gave him £150.

[br]

Bibliography

1841, British patent no. 8,783; 1843, British patent no. 9,745; 1845, British patent no.

10,838; 1847, British patent no. 11,584; 1852, British patent no. 14,146 (all for electric clocks).

1852, A Short History of the Electric Clocks with Explanation of Their Principles and

Mechanism and Instruction for Their Management and Regulation, London; reprinted 1973, introd. W.Hackmann, London: Turner \& Devereux (as the title implies, this pamphlet was probably intended for the purchasers of his clocks).

Further Reading

The best account of Bain's life and work is in papers by C.A.Aked in Antiquarian Horology: "Electricity, magnetism and clocks" (1971) 7: 398–415; "Alexander Bain, the father of electrical horology" (1974) 9:51–63; "An early electric turret clock" (1975) 7:428–42. These papers were reprinted together (1976) in A Conspectus of Electrical Timekeeping, Monograph No. 12, Antiquarian Horological Society: Tilehurst.

J.Finlaison, 1834, An Account of Some Remarkable Applications of the Electric Fluid to the Useful Arts by Alexander Bain, London (a contemporary account between Wheatstone and Bain over the invention of the electric clock).

J.Munro, 1891, Heroes of the Telegraph, Religious Tract Society.

J.Malster \& M.J.Bowden, 1976, "Facsimile. A Review", Radio \&Electronic Engineer 46:55.

D.J.Weaver, 1982, Electrical Clocks and Watches, Newnes.

T.Hunkin, 1993, "Just give me the fax", New Scientist (13 February):33–7 (provides details of Bain's and later fax devices).

See also: Bakewell, Frederick C.

DV / KF

Olympic broadcasting organization (OBO)

1. Олимпийская вещательная организация (ОВО)

 

Олимпийская вещательная организация (ОВО)
Организация, отвечающая за производство ITVR-сигналов, а также за предоставление вещательным компаниям оборудования и услуг, необходимых для трансляции Игр. В дополнение к производству ITVR- сигналов, OBO должна обеспечить установку и работу технических средств вещания в местах проведения Игр и в международном вещательном центре, оказывать вещательные телекоммуникационные и другие услуги, которые могут потребоваться для односторонней трансляции Игр, и обслуживать правообладателей, выступая в роли связующего звена с ОКОИ и другими местными организациями.
[Департамент лингвистических услуг Оргкомитета «Сочи 2014». Глоссарий терминов]

EN

Olympic broadcasting organization (OBO)
Organization, which has the responsibility of producing the ITVR Signals and for the further purpose of providing broadcasters with the facilities and services necessary for broadcasting the Games. In addition to generating the ITVR Signals, the OBO must install and operate the technical broadcasting facilities at the venues and the international broadcast center, provide broadcast telecommunications and other services that may be required for the unilateral broadcast coverage of the Games, and serve the rights holders by acting as the interface with the OCOG and other local organizations.
[Департамент лингвистических услуг Оргкомитета «Сочи 2014». Глоссарий терминов]

Тематики

• спорт (коммуникации и средства массовой информации)

EN

• Olympic broadcasting organization (OBO)

Branly, Edouard Eugène

SUBJECT AREA: Broadcasting, Electronics and information technology, Telecommunications

[br]

b. 23 October 1844 Amiens, France

d. 24 March 1940 Paris, France

[br]

French electrical engineer, who c.1890 invented the coherer for detecting radio waves.

[br]

Branly received his education at the Lycée de Saint Quentin in the Département de l'Aisne and at the Henri IV College of Paris University, where he became a Fellow of the University, graduating as a Doctor of Physics in 1873. That year he was appointed a professor at the College of Bourges and Director of Physics Instruction at the Sorbonne. Three years later he moved to the Free School in Paris as Professor of Advanced Studies. In addition to these responsibilities, he qualified as an MD in 1882 and practised medicine from 1896 to 1916. Whilst carrying out experiments with Hertzian (radio) waves in 1890, Branly discovered that a tube of iron filings connected to a source of direct voltage only became conductive when the radio waves were present. This early form of rectifier, which he called a coherer and which needed regular tapping to maintain its response, was used to operate a relay when the waves were turned on and off by Morse signals, thus providing the first practical radio communication.

[br]

Principal Honours and Distinctions

Papal Order of Commander of St George 1899. Légion d'honneur, Chevalier 1900, Commandeur 1925. Osiris Prize (jointly with Marie Curie) 1903. Argenteuil Prize and Associate of the Royal Belgian Academy 1910. Member of the Academy of Science 1911. State Funeral at Notre Dame Cathedral.

Bibliography

Amongst his publications in Comptes rendus were "Conductivity of mediocre conductors", "Conductivity of gases", "Telegraphic conduction without wires" and "Conductivity of imperfect conductors realised at a distance by wireless by spark discharge of a capacitor".

Further Reading

E.Hawkes, 1927, Pioneers of Wireless, London: Methuen. E.Larien, 1971, A History of Invention, London: Victor Gollancz.

V.J.Phillips: 1980, Early Radio Wave Detectors, London: Peter Peregrinus.

See also: Hertz, Heinrich Rudolph; Marconi, Marchese Guglielmo

KF

Faure, Camille Alphonse

SUBJECT AREA: Electricity

[br]

b. 21 May 1840 Vizille, France

d. September 1898

[br]

French chemist, inventor of an improved method of preparing the plates for Planté lead-acid secondary cells.

[br]

After technical training at the Ecole des Arts et Métiers at Aix, Faure was employed superintending the erection of factories in France and England. These included the Cotton Powder Company plant in Faversham for the manufacture of the explosive Tonite invented by Faure. He also invented distress signals used by the merchant navy. It was between 1878 and 1880 that he performed his most important work, the improvement of the Planté cell. Faure's invention of coating the lead plates with a paste of lead oxide substantially reduced the time taken to form the plates. Their construction was subsequently further improved by Swan and others. These developments appeared at a particularly opportune time because lead-acid secondary cells found immediate application in telegraphy and later in electric lighting and traction systems, where their use resulted in reduced costs of providing supplies during peak-load periods. In his later years Faure's attention was directed to other electrochemical problems, including the manufacture of aluminium.

[br]

Bibliography

1881, "Sur la pile secondaire de M C.Faure", Comptes rendus 92:951–3 (announcing his cell).

11 January 1881, British patent no. 129 (Faure's improvement of the Planté cell).

Further Reading

Electrician (1882) 7:122–3 (describes the Faure cell).

G.Wood Vinal, 1955, Storage Batteries, 4th edn, London (describes later developments).

GW