interference+method

интерференционный способ

Naval: pressure-wave interference method

метод двухцветной интерференции

Makarov: two color interference method

метод многолучевой интерференции

Makarov: multiple-beam interference method

Interferenzverfahren

n < phys> ■ interference method

интерференционный способ измерения скорости

pressure-wave interference method of velocity measurement

метод многолучевой интерференции

multiple-beam interference method

интерференционный способ

pressure-wave interference method

интерференционный

1. interference

интерференционный спектр — interference spectrum

интерференционный прибор — interference apparatus

интерференционный микроскоп — interference microscope

интерференционный поглотитель — interference absorber

интерференционный компаратор — interference comparator

2. interferometric

интерференционный метод — interferometric method

интерференционный дилатометр — interferometric dilatometer

unzulässig

Adj. inadmissible; Geschwindigkeit etc.: above the legal limit, excessive; JUR., Beeinflussung: undue; unzulässige Code-Kombination EDV invalid code combination; unzulässiger Befehl / unzulässiges Zeichen EDV invalid command

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prohibited; invalid; undue; inadmissible; illegal; forbidden; unallowable

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ụn|zu|läs|sig

adj (AUCH JUR)

inadmissible; Gebrauch improper; Beeinflussung undue; Belastung, Geschwindigkeit excessive

für unzulässig erklären (Jur) — to rule out

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1) (not allowable.) inadmissible

2) (not correct according to what is regularly done, especially in meetings etc: He was out of order in saying that.) out of order

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un·zu·läs·sig

[ˈʊntsu:lɛsɪç]

adj inadmissible

\unzulässige Maßnahmen/Methoden improper measures/methods

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Adjektiv inadmissible; undue <influence, interference, delay>; improper <method, use, etc.>

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unzulässig adj inadmissible; Geschwindigkeit etc: above the legal limit, excessive; JUR, Beeinflussung: undue;

unzulässige Code-Kombination IT invalid code combination;

unzulässiger Befehl/unzulässiges Zeichen IT invalid command

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Adjektiv inadmissible; undue <influence, interference, delay>; improper <method, use, etc.>

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adj.

illegal adj.

inadmissible adj.

objectionable adj.

unallowable adj.

undue adj. adv.

inadmissibly adv.

Verfahren

Verfahren n 1. COMP procedure (Programm); 2. GEN process, procedure; 3. IND process, technique; 4. MGT method; 5. RECHT procedure proceedings, action, suit (Rechtsstreit); 6. ADMIN procedure • ein Verfahren für ungültig erklären RECHT extinguish an action • gegen jmdn. ein Verfahren anstrengen RECHT bring a lawsuit against sb

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n 1. < Comp> Programm procedure; 2. < Geschäft> process, procedure; 3. < Ind> process, technique; 4. < Mgmnt> method; 5. < Recht> procedure Rechtsstreit proceedings, action, suit; 6. < Verwalt> procedure ■ ein Verfahren für ungültig erklären < Recht> extinguish an action ■ gegen jmdn. ein Verfahren anstrengen < Recht> bring a lawsuit against sb

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Verfahren
(Arbeitsvorgang) operation, course, (Behandlung) treatment, (Gericht) procedure, proceeding[s], process, case, suit at law (US), lawsuit (US), (Handlungsweise) deal (coll.), dealings, (Herstellung) process, method, technique, departure, (Methode) manner, method, plan, line, way, mode, (Schema) policy, system;
• in einem schwebenden Verfahren pendente lite (lat.);
• abgekürztes Verfahren summary proceeding;
• aufeinander abgestimmtes Verfahren concerted practices;
• abgetrenntes Verfahren separate trial;
• anhängiges Verfahren case at law, proceedings instituted;
• beschleunigtes Verfahren speedup;
• bildgebendes Verfahren imaging technique;
• disziplinarisches Verfahren disciplinary proceedings;
• einheitliches Verfahren standard practice, uniform procedure;
• Einsparungen ermöglichendes Verfahren saver;
• gerichtliches Verfahren legal proceedings, judicial process (proceedings);
• getrenntes Verfahren separate action;
• industrielles Verfahren know-how, industrial technique;
• konkursrechtliches Verfahren bankruptcy proceedings (procedure);
• kostspieliges Verfahren costly proceedings, wasteful process;
• neuartiges Verfahren novel method;
• neues Verfahren new departure;
• ordentliches Verfahren regular process, ordinary proceedings;
• ordnungsgemäßes Verfahren due process of law;
• patentfähiges Verfahren patentable process;
• patentiertes Verfahren patented process;
• schiedsgerichtliches Verfahren arbitration procedure;
• schriftliches Verfahren written proceedings;
• übliches steuernsparendes Verfahren tax-saving pattern;
• überholtes Verfahren outmoded process;
• [allgemein] übliches Verfahren common practice;
• ungerechtes Verfahren unfair hearing;
• ungesetzliches Verfahren illegal proceedings;
• ungültiges Verfahren void (irregular) process, mistrial;
• unvorschriftsmäßiges Verfahren undue proceedings;
• verbessertes Verfahren improved process;
• Verfahren bei der Aufstellung des Haushalts budget procedure;
• Verfahren bei der Aufstellung des Werbeetats (Werbebudgets) advertising-budget procedure;
• Verfahren zur besseren Ausnutzung elektronischer Datenverarbeitungsanlagen time-sharing of data-processing machines;
• Verfahren zur Beilegung von Tarifstreitigkeiten disputes procedure;
• Verfahren zur Festsetzung der Folgeprämie renewal procedure;
• Verfahren zur Festsetzung eines Prioritätsrechtes (Patentrecht) interference proceedings;
• Verfahren zur Feststellung der Schadenhöhe writ of inquiry [after judgment by default];
• Verfahren zur Freigabe von Geheimmaterial declassification procedure;
• Verfahren der freiwilligen Gerichtsbarkeit non-contentious business;
• Verfahren zur Gründung einer Kapitalgesellschaft incorporation procedure (US);
• Verfahren im Interesse einer Klägergruppe class action (suit);
• Verfahren in Nachlassangelegenheiten administration suit;
• Verfahren zur Offenlegung der Vermögensverhältnisse equitable garnishment, supplementary proceedings (US);
• Verfahren eines integrierten Planungs-, Programmierungs- und Haushaltssystems Planning-Programming-Budgeting System;
• Verfahren zur Regelung arbeitsrechtlicher Streitigkeiten disputes procedure;
• Verfahren zur Regelung von Versicherungsansprüchen claim procedure;
• Verfahren in der Revisionsinstanz proceedings in error;
• Verfahren in Steuersachen process in tax proceedings;
• Verfahren in Warenzeichenangelegenheiten trademark procedure;
• Verfahren abtrennen to separate a case;
• Verfahren anstrengen to institute legal proceedings, to bring a suit;
• neues Verfahren anwenden to take a new departure;
• sein übliches Verfahren anwenden to follow one’s standard practice;
• Verfahren wieder aufnehmen to reopen a case;
• neue Verfahren ausprobieren to experiment with new methods;
• gerichtliches Verfahren aussetzen to stay (suspend) the proceedings, to arrest judgment;
• Verfahren beschleunigen to accelerate proceedings, to speed up procedures;
• Verfahren gegen j. in Gang bringen to take out a process against s. o.;
• Verfahren durchführen to proceed with a case, to carry on legal proceedings;
• neue technologische Verfahren in der Industrie einführen to make technical innovations in industry;
• in ein laufendes Verfahren eingreifen to publish comment on cases pending;
• Verfahren wegen Amtsmissbrauchs einleiten to take misfeasance proceedings;
• Verfahren einstellen to abate proceedings, to dismiss a case;
• einheitliches Verfahren erarbeiten to standardize procedure;
• ordnungsgemäßes Verfahren sicherstellen to regularize the proceedings;
• sich einem schiedsrichterlichen Verfahren unterwerfen to submit a claim for arbitration;
• Verfahren verschleppen to delay the proceedings;
• in einem schiedsgerichtlichen Verfahren tätig werden to arbitrate between parties to a suit;
• zu den Kosten des Verfahrens verurteilt werden to be condemned in (ordered to pay) the costs.

Lippman, Gabriel

SUBJECT AREA: Photography, film and optics

[br]

b. 16 August 1845 Hallerick, Luxembourg

d. 14 July 1921 at sea, in the North Atlantic

[br]

French physicist who developed interference colour photography.

[br]

Born of French parents, Lippman's work began with a distinguished career in classics, philosophy, mathematics and physics at the Ecole Normale in Luxembourg. After further studies in physics at Heidelberg University, he returned to France and the Sorbonne, where he was in 1886 appointed Director of Physics. He was a leading pioneer in France of research into electricity, optics, heat and other branches of physics.

In 1886 he conceived the idea of recording the existence of standing waves in light when it is reflected back on itself, by photographing the colours so produced. This required the production of a photographic emulsion that was effectively grainless: the individual silver halide crystals had to be smaller than the shortest wavelength of light to be recorded. Lippman succeeded in this and in 1891 demonstrated his process. A glass plate was coated with a grainless emulsion and held in a special plate-holder, glass towards the lens. The back of the holder was filled with mercury, which provided a perfect reflector when in contact with the emulsion. The standing waves produced during the exposure formed laminae in the emulsion, with the number of laminae being determined by the wavelength of the incoming light at each point on the image. When the processed plate was viewed under the correct lighting conditions, a theoretically exact reproduction of the colours of the original subject could be seen. However, the Lippman process remained a beautiful scientific demonstration only, since the ultra-fine-grain emulsion was very slow, requiring exposure times of over 10,000 times that of conventional negative material. Any method of increasing the speed of the emulsion also increased the grain size and destroyed the conditions required for the process to work.

[br]

Principal Honours and Distinctions

Royal Photographic Society Progress Medal 1897. Nobel Prize (for his work in interference colour photography) 1908.

Further Reading

J.S.Friedman, 1944, History of Colour Photography, Boston.

Brian Coe, 1978, Colour Photography: The First Hundred Years, London. Gert Koshofer, 1981, Farbfotografie, Vol. I, Munich.

BC

Lumière, Auguste

SUBJECT AREA: Photography, film and optics

[br]

b. 19 October 1862 Besançon, France

d. 10 April 1954 Lyon, France

[br]

French scientist and inventor.

[br]

Auguste and his brother Louis Lumière (b. 5 October 1864 Besançon, France; d. 6 June 1948 Bandol, France) developed the photographic plate-making business founded by their father, Charles Antoine Lumière, at Lyons, extending production to roll-film manufacture in 1887. In the summer of 1894 their father brought to the factory a piece of Edison kinetoscope film, and said that they should produce films for the French owners of the new moving-picture machine. To do this, of course, a camera was needed; Louis was chiefly responsible for the design, which used an intermittent claw for driving the film, inspired by a sewing-machine mechanism. The machine was patented on 13 February 1895, and it was shown on 22 March 1895 at the Société d'Encouragement pour l'In-dustrie Nationale in Paris, with a projected film showing workers leaving the Lyons factory. Further demonstrations followed at the Sorbonne, and in Lyons during the Congrès des Sociétés de Photographie in June 1895. The Lumières filmed the delegates returning from an excursion, and showed the film to the Congrès the next day. To bring the Cinématographe, as it was called, to the public, the basement of the Grand Café in the Boulevard des Capuchines in Paris was rented, and on Saturday 28 December 1895 the first regular presentations of projected pictures to a paying public took place. The half-hour shows were an immediate success, and in a few months Lumière Cinématographes were seen throughout the world.

The other principal area of achievement by the Lumière brothers was colour photography. They took up Lippman's method of interference colour photography, developing special grainless emulsions, and early in 1893 demonstrated their results by lighting them with an arc lamp and projecting them on to a screen. In 1895 they patented a method of subtractive colour photography involving printing the colour separations on bichromated gelatine glue sheets, which were then dyed and assembled in register, on paper for prints or bound between glass for transparencies. Their most successful colour process was based upon the colour-mosaic principle. In 1904 they described a process in which microscopic grains of potato starch, dyed red, green and blue, were scattered on a freshly varnished glass plate. When dried the mosaic was coated with varnish and then with a panchromatic emulsion. The plate was exposed with the mosaic towards the lens, and after reversal processing a colour transparency was produced. The process was launched commercially in 1907 under the name Autochrome; it was the first fully practical single-plate colour process to reach the public, remaining on the market until the 1930s, when it was followed by a film version using the same principle.

Auguste and Louis received the Progress Medal of the Royal Photographic Society in 1909 for their work in colour photography. Auguste was also much involved in biological science and, having founded the Clinique Auguste Lumière, spent many of his later years working in the physiological laboratory.

[br]

Further Reading

Guy Borgé, 1980, Prestige de la photographie, Nos. 8, 9 and 10, Paris. Brian Coe, 1978, Colour Photography: The First Hundred Years, London ——1981, The History of Movie Photography, London.

Jacques Deslandes, 1966, Histoire comparée du cinéma, Vol. I, Paris. Gert Koshofer, 1981, Farbfotografie, Vol. I, Munich.

BC

создавать

. вызывать; образовывать; организовывать; проектировать; разрабатывать

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The compounds that nature can produce...

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The magnetic moment produces a diamagnetic effect.

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It is this reaction which builds up the reservoir of activated molecules.

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Displacing a particle in one direction brings about a force in the opposite direction.

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Within a short time of this discovery a whole new field of research had been launched.

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This vibrational resonance can create new photons.

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Industrial and professional societies have brought into being (or existence) a wide variety of standards.

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Where the valley is narrow the earthflow toe forms a dam, sometimes creating a lake.

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To build up (or produce) sufficient pressure so as to ensure...

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These forces cannot develop torque.

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If the rotor is given the shape of a polygon, the lines of force exert the desired torque.

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In large crystals the dislocations interact to generate new ones.

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The detonation wave upon impacting the wave shaper generates a shock wave.

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The heat generated by magnetization...

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The feedback generates parasitic laser oscillations.

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The resistance element generates precision voltages.

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The use of a driving belt could give rise to vibration.

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The model was rotated in a centrifuge to induce centrifugal forces.

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The pump produces a vacuum of 0.1 mm.

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When a current passes through a wire, it sets up a magnetic field around the wire.

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The magnetic field sets up a magnetomotive force.

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The flywheels set up in the spring-mounted screen a motion which...

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The heating of the coils sets up a ventilating draught.

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The object of the experiment is to build up a high current of charged particles.

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The gradient of viscous shear stresses establishes a steady-state concentration gradient.

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These energy transitions give rise to pockets of photons.

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This brings with it acute problems of electrical interference.

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In the past 20 years the electronics industry has generated many completely new technological systems.

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The media bring into existence and cultivate a new form of common consciousness.

II

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Systems with odd numbers of channels can also be devised.

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An instrument has been created (or devised) for...

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The research staffs are evolving workable designs.

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The engineers have come up with an improved technique for...

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He originated the projection method.

метод интерференционного интеграла

Optics: interference integral method

метод интерференционного интеграла

опт. interference integral method

микроскоп

microscope, scope

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микроско́п м.
microscope

микроско́п даё́т, напр. прямо́е или перевё́рнутое изображе́ние — a microscope forms an, e. g., erect or inverted image

микроско́п испо́льзуется для наблюде́ния по ме́тоду, напр. тё́много или све́тлого по́ля — a microscope can be used for, e. g., dark-field or bright-field work

наблюда́ть в микроско́п — observe with a microscope

микроско́п предназна́чен для наблюде́ния в, напр. проходя́щем или отражё́нном све́те — a microscope is intended for, e. g., transmitted or reflected light work

микроско́п рабо́тает по при́нципу фа́зового контра́ста — a microscope operates by the phase-contrast method

автоэлектро́нный микроско́п — field-emission microscope

бинокуля́рный микроско́п — binocular microscope

биологи́ческий микроско́п — biological microscope

голографи́ческий микроско́п — holographic microscope

микроско́п для я́дерных эму́льсий — nuclear-emulsion microscope

измери́тельный микроско́п — measuring microscope

иммерсио́нный микроско́п — immersion microscope

инверти́рованный микроско́п — inverted-stage microscope

инструмента́льный микроско́п — toolmaker's [tool-room] microscope

интерференцио́нный микроско́п — interference microscope

инфракра́сный микроско́п — infra-red microscope

ио́нный микроско́п — field-ion microscope

ла́зерный микроско́п — laser microscope

люминесце́нтный микроско́п — fluorescence microscope

магни́тный микроско́п — magnetic microscope

металлографи́ческий микроско́п — ( без фотокамеры) metallurgical microscope; ( с встроенной фотокамерой) metallographic microscope, metallograph

монокуля́рный микроско́п — monocular microscope

опти́ческий микроско́п — light [optical] microscope

отсчё́тный микроско́п — reading microscope

поляризацио́нный микроско́п — polarizing microscope

проекцио́нный микроско́п — projection microscope

прото́нный микроско́п — proton microscope

ра́стровый микроско́п — scanning [flying-spot] microscope

рентге́новский микроско́п — X-ray microscope

микроско́п с бегу́щим лучо́м — scanning [flying-spot] microscope

микроско́п с больши́м увеличе́нием — high-power microscope

светово́й микроско́п — light microscope

микроско́п с ма́лым увеличе́нием — low-power microscope

стереоскопи́ческий микроско́п — stereoscopic microscope, stereomicroscope

стереоскопи́ческий микроско́п обеспе́чивает объё́мное восприя́тие объе́кта — a stereomicroscope produces the sensation of depth in an object

микроско́п с цифровы́м отсчё́том — digitized microscope

телевизио́нный микроско́п — television microscope

тенево́й микроско́п — shadow microscope

ультрафиоле́товый микроско́п — ultra-violet microscope

универса́льный микроско́п — universal stage microscope

фазоконтра́стный микроско́п — phase-contrast microscope

фотоэлектри́ческий микроско́п — photoelectric microscope

шка́ловый микроско́п — reading microscope

электро́нный микроско́п — electron microscope

электро́нный, отража́тельный микроско́п — reflection electron microscope

электро́нный, просве́чивающий микроско́п — transmission electron microscope

электро́нный, ра́стровый микроско́п — scanning electron microscope

эмиссио́нный микроско́п — field-emission microscope

в настоящее время общепринято, что

В настоящее время общепринято, что-- Today it is well accepted that the optical interference technique is the most accurate method for the measurement of ultra-thin gas bearing separations.

Störspannungsmessmethode

Störspannungsmessmethode f radio interference test method (z. B. bei Teilentladungsmessung)

микроскоп

м. microscope

наблюдать в микроскоп — observe with a microscope

микроскоп работает по принципу фазового контраста — a microscope operates by the phase-contrast method

автоэлектронный микроскоп — field-emission microscope

бинокулярный микроскоп — binocular microscope

биологический микроскоп — biological microscope

голографический микроскоп — holographic microscope

микроскоп для ядерных эмульсий — nuclear-emulsion microscope

измерительный микроскоп — measuring microscope

иммерсионный микроскоп — immersion microscope

инвертированный микроскоп — inverted-stage microscope

интерференционный микроскоп — interference microscope

инфракрасный микроскоп — infra-red microscope

ионный микроскоп — field-ion microscope

лазерный микроскоп — laser microscope

люминесцентный микроскоп — fluorescence microscope

магнитный микроскоп — magnetic microscope

металлографический микроскоп — metallurgical microscope; metallographic microscope

монокулярный микроскоп — monocular microscope

оптический микроскоп — light microscope

отсчётный микроскоп — reading microscope

поляризационный микроскоп — polarizing microscope

проекционный микроскоп — projection microscope

протонный микроскоп — proton microscope

растровый микроскоп — scanning microscope

рентгеновский микроскоп — X-ray microscope

микроскоп с бегущим лучом — scanning microscope

микроскоп с большим увеличением — high-power microscope

световой микроскоп — light microscope

микроскоп с малым увеличением — low-power microscope

стереоскопический микроскоп — stereoscopic microscope

стереоскопический микроскоп обеспечивает объёмное восприятие объекта — a stereomicroscope produces the sensation of depth in an object

микроскоп с цифровым отсчётом — digitized microscope

телевизионный микроскоп — television microscope

теневой микроскоп — shadow microscope

ультрафиолетовый микроскоп — ultra-violet microscope

универсальный микроскоп — universal stage microscope

фазоконтрастный микроскоп — phase-contrast microscope

фотоэлектрический микроскоп — photoelectric microscope

шкаловый микроскоп — reading microscope

темнопольный микроскоп — dark-field microscope

видимый в микроскоп — visible by the microscope

отражательный микроскоп — reflection microscope

широкопольный микроскоп — wide-field microscope

флуоресцентный микроскоп — fluorescence microscope

Braun, Karl Ferdinand

SUBJECT AREA: Electricity, Electronics and information technology, Telecommunications

[br]

b. 6 June 1850 Fulda, Hesse, Germany

d. 20 April 1918 New York City, New York, USA

[br]

German physicist who shared with Marconi the 1909 Nobel Prize for Physics for developments in wireless telegraphy; inventor of the cathode ray oscilloscope.

[br]

After obtaining degrees from the universities of Marburg and Berlin (PhD) and spending a short time as Headmaster of the Thomas School in Berlin, Braun successively held professorships in theoretical physics at the universities of Marburg (1876), Strasbourg (1880) and Karlsruhe (1883) before becoming Professor of Experimental Physics at Tübingen in 1885 and Director and Professor of Physics at Strasbourg in 1895.

During this time he devised experimental apparatus to determine the dielectric constant of rock salt and developed the Braun high-tension electrometer. He also discovered that certain mineral sulphide crystals would only conduct electricity in one direction, a rectification effect that made it possible to detect and demodulate radio signals in a more reliable manner than was possible with the coherer. Primarily, however, he was concerned with improving Marconi's radio transmitter to increase its broadcasting range. By using a transmitter circuit comprising a capacitor and a spark-gap, coupled to an aerial without a spark-gap, he was able to obtain much greater oscillatory currents in the latter, and by tuning the transmitter so that the oscillations occupied only a narrow frequency band he reduced the interference with other transmitters. Other achievements include the development of a directional aerial and the first practical wavemeter, and the measurement in Strasbourg of the strength of radio waves received from the Eiffel Tower transmitter in Paris. For all this work he subsequently shared with Marconi the 1909 Nobel Prize for Physics.

Around 1895 he carried out experiments using a torsion balance in order to measure the universal gravitational constant, g, but the work for which he is probably best known is the addition of deflecting plates and a fluorescent screen to the Crooke's tube in 1897 in order to study the characteristics of high-frequency currents. The oscilloscope, as it was called, was not only the basis of a now widely used and highly versatile test instrument but was the forerunner of the cathode ray tube, or CRT, used for the display of radar and television images.

At the beginning of the First World War, while in New York to testify in a patent suit, he was trapped by the entry of the USA into the war and remained in Brooklyn with his son until his death.

[br]

Principal Honours and Distinctions

Nobel Prize for Physics (jointly with Marconi) 1909.

Bibliography

1874, "Assymetrical conduction of certain metal sulphides", Pogg. Annal. 153:556 (provides an account of the discovery of the crystal rectifier).

1897, "On a method for the demonstration and study of currents varying with time", Wiedemann's Annalen 60:552 (his description of the cathode ray oscilloscope as a measuring tool).

Further Reading

K.Schlesinger \& E.G.Ramberg, 1962, "Beamdeflection and photo-devices", Proceedings of the Institute of Radio Engineers 50, 991.

KF