second cladding

second cladding

Телекоммуникации: вторая оболочка (оптокабеля)

second cladding

вторая оболочка ( оптокабеля)

cladding

оболочка, покрытие

- depressed inner cladding

- fiber cladding
- first cladding
- homogeneous cladding
- lossy cladding
- outer cladding
- second cladding
- third cladding

mode

1) режим

2) состояние

3) мода, тип ( волны)

•

- access mode

- acoustic mode
- active mode
- adaptive mode
- alternate mode
- ANS/FAX mode
- answering mode
- assemble mode
- asymmetrical mode
- asynchronous balanced mode
- asynchronous transfer mode
- authorized reception mode
- auto document mode
- autoinformer mode
- automatic mode
- automatic reception mode
- auto-night mode
- backup mode
- basic control mode
- biharmonical mode
- bound mode
- buffer mode
- byte mode
- center mark mode
- channel mode
- circuit-transfer mode
- cladding mode
- client-server mode
- coasting mode
- combined mode
- command mode
- common mode
- communication mode
- confidential mode
- continuous emission mode
- continuous mode
- conversational mode
- correction mode
- coupled modes
- cutoff mode
- data mode
- data-processing mode
- day/night mode
- delayed ARM mode
- DEMO mode
- detail mode
- detection mode
- direct sending mode
- display mode
- dual mode
- duplex mode
- erase mode
- evanescent mode
- executive mode
- expansion modes
- external synchronization mode
- Fax mode
- fine mode
- first-type oscillation mode
- forced mode
- frame mode
- fundamental mode
- generator mode
- ghost mode
- group mode
- guard mode
- half-duplex mode
- half-speed mode
- half-tone mode
- hierarchical mode
- high-power mode
- holding mode
- hollow-beam mode
- home-only mode
- hybrid mode
- idling mode
- instant ARM mode
- internal synchronization mode
- interrupt mode
- interruptible current mode
- inversed mode
- key mode
- landscape mode
- leaky mode
- light-tensioned mode
- limiting mode
- linear mode
- line-art mode
- line-hold mode
- line-holding mode
- listening mode
- local mode
- lock mode
- long-distance mode
- long-play mode
- long-time mode
- loudly mode
- low signal mode
- lugdown mode
- macroblock mode
- magnetostatic mode
- manual mode
- master mode
- matched operation mode
- matching mode
- memory lock mode
- minimal mode
- mode of behavior
- modulated mode
- monitor mode
- mono mode
- multicopy mode
- multiplex mode
- multipoint mode
- multisort document reception mode
- net mode
- nonpublic mode
- nontransparent mode
- normal mode
- off mode
- off-normal mode
- on-line mode
- on-link mode
- open-phase mode
- operating mode
- orthonormal modes
- overseas mode
- overtensioned mode
- parallel mode
- part load mode
- partial load mode
- peak mode
- periodic mode
- phone-only mode
- photo mode
- photodiode mode
- photogalvanic mode
- phototransistor mode
- pilot mode
- playback mode
- polling reception mode
- polling standby mode
- polling-transmission mode
- portrait mode
- potential mode
- precritical mode
- prediction mode
- printer mode
- private mode
- propagation mode
- pulsed mode
- quasi-cyclic mode
- quasi-key mode
- quick-record mode
- radiation mode
- rated power mode
- real-time mode
- receive mode
- recursive short-time mode
- redial mode
- remote-receiving mode
- rental mode
- rest mode
- reversing mode
- running-wave mode
- sample-and-hold mode
- saturation mode
- save dial mode
- scan mode
- second-type oscillation mode
- self-exciting oscillation mode
- self-oscillating mode
- send later mode
- sequential lossless mode
- serial mode
- series mode
- servicing mode
- setup mode
- shared fax mode
- short-time mode
- silence detection mode
- silently mode
- sleep mode
- soft self-exciting mode
- soft-control mode
- soft-controlling mode
- sound mode
- special scanning mode
- standard mode
- standby mode
- standing wave mode
- start mode
- starting mode
- start-stop mode
- stereo mode
- stop mode
- storage mode
- substitute reception mode
- superfine mode
- switching mode
- symmetrical mode
- synchronous-transfer mode
- synchronous-transmission mode
- TEL mode
- TEL/FAX mode
- telegraph mode
- telephone mode
- tensioned mode
- transfer mode
- transmission dead-line mode
- transmission mode
- transverse electric-and-magnetic mode
- transverse magnetic mode
- transverse-electric mode
- traveling wave mode
- triggering mode
- tuning mode
- uncoupled modes
- undertensioned mode
- unlock mode
- unstable mode
- valve mode
- vibrating mode
- voice-call mode
- waiting mode
- winding mode
- wireless-access mode
- XX mode

Gropius, Walter Adolf

SUBJECT AREA: Architecture and building

[br]

b. 18 May 1883 Berlin, Germany

d. 5 July 1969 Boston, USA

[br]

German co-founder of the modern movement of architecture.

[br]

A year after he began practice as an architect, Gropius was responsible for the pace-setting Fagus shoe-last factory at Alfeld-an-der-Leine in Germany, one of the few of his buildings to survive the Second World War. Today the building does not appear unusual, but in 1911 it was a revolutionary prototype, heralding the glass curtain walled method of non-load-bearing cladding that later became ubiquitous. Made from glass, steel and reinforced concrete, this factory initiated a new concept, that of the International school of modern architecture.

In 1919 Gropius was appointed to head the new School of Art and Design at Weimar, the Staatliches Bauhaus. The school had been formed by an amalgamation of the Grand Ducal schools of fine and applied arts founded in 1906. Here Gropius put into practice his strongly held views and he was so successful that this small college, which trained only a few hundred students in the limited years of its existence, became world famous, attracting artists, architects and students of quality from all over Europe.

Gropius's idea was to set up an institution where students of all the arts and crafts could work together and learn from one another. He abhorred the artificial barriers that had come to exist between artists and craftsmen and saw them all as interdependent. He felt that manual dexterity was as essential as creative design. Every Bauhaus student, whatever the individual's field of work or talent, took the same original workshop training. When qualified they were able to understand and supervise all the aesthetic and constructional processes that made up the scope of their work.

In 1924, because of political changes, the Weimar Bauhaus was closed, but Gropius was invited to go to Dessau to re-establish it in a new purpose-built school which he designed. This group of buildings became a prototype that designers of the new architectural form emulated. Gropius left the Bauhaus in 1928, only a few years before it was finally closed due to the growth of National Socialism. He moved to England in 1934, but because of a lack of architectural opportunities and encouragement he continued on his way to the USA, where he headed the Department of Architecture at Harvard University's Graduate School of Design from 1937 to 1952. After his retirement from there Gropius formed the Architect's Collaborative and, working with other architects such as Marcel Breuer and Pietro Belluschi, designed a number of buildings (for example, the US Embassy in Athens (1960) and the Pan Am Building in New York (1963)).

[br]

Bibliography

1984, Scope of Total Architecture, Allen \& Unwin.

Further Reading

N.Pevsner, 1936, Pioneers of the Modern Movement: From William Morris to Walter Gropius, Penguin.

C.Jenck, 1973, Modern Movements in Architecture, Penguin.

H.Probst and C.Shädlich, 1988, Walter Gropius, Berlin: Ernst \& Son.

DY

Kao, Charles Kuen

SUBJECT AREA: Electronics and information technology, Telecommunications

[br]

b. 4 November 1933 Shanghai, China

[br]

Chinese electrical engineer whose work on optical fibres did much to make optical communications a practical reality.

[br]

After the Second World War, Kao moved with his family to Hong Kong, where he went to St Joseph's College. To further his education he then moved to England, taking his "A" Levels at Woolwich Polytechnic. In 1957 he gained a BSc in electrical engineering and then joined Standard Telephones and Cables Laboratory (STL) at Harlow. Following the discovery by others in 1960 of the semiconductor laser, from 1963 Kao worked on the problems of optical communications, in particular that of achieving attenuation in optical cables low enough to make this potentially very high channel capacity form of communication a practical proposition; this problem was solved by suitable cladding of the fibres. In the process he obtained his PhD from University College, London, in 1965. From 1970 until 1974, whilst on leave from STL, he was Professor of Electronics and Department Chairman at the Chinese University of Hong Kong, then in 1982–7 he was Chief Scientist and Director of Engineering with the parent company ITT in the USA. Since 1988 he has been Vice-Chancellor of Hong Kong University.

[br]

Principal Honours and Distinctions

Franklin Institute Stuart Ballantine Medal 1977. Institute of Electrical and Electronic Engineers Morris N.Liebmann Memorial Prize 1978; L.M.Ericsson Prize 1979. Institution of Electrical Engineers A.G.Bell Medal 1985; Faraday Medal 1989. American Physical Society International Prize for New Materials 1989.

Bibliography

1966, with G.A.Hockham, "Dielectric fibre surface waveguides for optical frequencies", Proceedings of the Institution of Electrical Engineers 113:1,151 (describes the major step in optical-fibre development).

1982, Optical Fibre Systems. Technology, Design \& Application, New York: McGraw- Hill.

1988, Optical Fibre, London: Peter Peregrinus.

Further Reading

W.B.Jones, 1988, Introduction to Optical Fibre Communications: R\&W Holt.

KF