independent+patent

Independent Patent

Business: IP

independent patent

независимый патент

Patent

Patent n (Pat.) PAT, RECHT patent, pat. • ein Patent anmelden PAT take out a patent • ein Patent erwirken PAT take out a patent • Patent ist angemeldet PAT application is pending

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n (Pat.) <Patent, Recht> patent (pat.) ■ ein Patent anmelden < Patent> take out a patent ■ ein Patent erwirken < Patent> take out a patent ■ Patent ist angemeldet < Patent> application is pending

* * *

Patent
patent, (Patenturkunde) [letters] patent;
• Patent angemeldet patent pending;
• durch ein Patent geschützt patented;
• abgelaufenes Patent patent lapsed, expired patent;
• älteres Patent prior patent;
• angefochtenes Patent patent sued on, contested patent;
• angemeldetes Patent patent pending;
• später angemeldetes Patent subsequent patent;
• bahnbrechendes Patent pioneer patent;
• nebeneinander bestehende Patente coexisting patents;
• blockiertes Patent blocking-off patent;
• einwandfreies Patent clean patent;
• endgültiges Patent complete patent;
• erloschenes Patent expired patent;
• erteiltes Patent patent issued (granted);
• nicht mehr geschütztes Patent expired patent;
• grundlegendes Patent pioneer (basic) patent;
• gültiges Patent patent in force, valid patent;
• jüngeres Patent subsequent patent;
• mangelhaftes Patent defective patent;
• nichtiges Patent void patent;
• selbstständiges Patent independent patent;
• strittiges Patent conflicting patent;
• umfassendes Patent blanket patent;
• verfallenes Patent lapsed (expired) patent;
• Patent anfechten to attack (avoid) a patent;
• Patent anmelden to file an application (apply, put up) for a patent, to give notice of a patent;
• Erfindung zum Patent anmelden to patent an invention;
• Patent aufgeben to surrender a patent;
• Patent aufrechterhalten to maintain a patent;
• Patent ausstellen to issue a patent;
• Patent ausüben to work a patent;
• Patent auswerten to exploit a patent;
• Patent beantragen to seek a patent;
• gleichzeitig ein Patent für ein und dieselbe Erfindung beantragen to interfere (US);
• Patent berichtigen to amend a patent;
• Patent besitzen to hold a patent;
• Patent bewerten to appraise a patent;
• Patent eintragen to register a patent;
• Patent enteignen to acquire a patent compulsorily;
• Patent erhalten to take out a patent;
• Patent in Geltung erhalten to keep a patent in force (alive);
• Patent für nichtig erklären to revoke (annul, nullify) a patent;
• Patent erteilen to grant (issue) a patent;
• Patent ungenutzt lassen to shelve a patent;
• Patent verfallen lassen to forfeit (abandon, drop) a patent;
• Patent löschen to cancel a patent;
• Patent praktisch verwertbar machen to reduce a patent to practice;
• Patent missbrauchen to abuse a patent privilege;
• durch Patente schützen to protect by patents;
• Patent gegen Ausnutzung schützen to protect a patent from infringement;
• zum Patent angemeldet sein to be put up for patent;
• Patent auf eine Basis stützen to base an invention;
• Patent übertragen to assign a patent;
• Patent umgehen to circumvent a patent;
• Patent verlängern to extend a patent;
• Patent verletzen to infringe a patent;
• Patent versagen (verweigern, vorenthalten) to refuse a patent, to withhold [the grant of] a patent;
• Patent verwerten to realize a patent, to use a patented product;
• auf ein Patent verzichten to drop (abandon) a patent;
• auf ein unberechtigtes Patent verzichten to surrender a patent;
• erloschenes Patent wiederherstellen to revive an expired patent;
• Patent zurücknehmen to revoke a patent;
• Patentabänderung variance;
• scheinbare Patentabänderung zu Umgehungszwecken colo(u)rable alteration;
• Patentabgabe royalty;
• Patentablauf expiration (expiry) of a patent;
• Patentabteilung patent department;
• Patentabtretung assignment of a patent.

selbstständiges Patent

selbstständiges Patent
independent patent

незалежний патент

independent patent

независимый патент

independent patent

независимый патент

independent patent

независим патент

independent patent

independent patents

selbstständig

selbstständig adj 1. COMP stand-alone; 2. GEN self-sufficient, unaffiliated; 3. PERS self-employed; 4. POL self-governing; 5. STEUER self-employed; 6. WIWI self-sufficient, unaffiliated, autarkic • sich selbstständig machen GEN, RECHT, V&M start one’s own business

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selbstständig
independent, in an independent capacity, on one’s own, free, self-employed, (autark) self-supporting, (freiberuflich tätig) free-lance, (Staat) autonomous, sovereign;
• selbstständig erwerbstätig self-employed;
• sich selbstständig gemacht haben to be on one’s own hook;
• selbstständig machen to emancipate;
• sich selbstständig machen to establish o. s. as a businessman, to set up (go into business) for o. s., to branch out on one’s own;
• selbstständig sein to be self-supporting (on one’s own, in business on one’s own account), to stand on one’s own legs;
• an selbstständiges Arbeiten gewohnt sein to be used to working independently;
• selbstständiger Beweis independent proof;
• selbstständige Einheit self-contained unit;
• selbstständiges Einzelhandelsgeschäft independent retail shop (store, US);
• selbstständiger Einzelhändler independent retailer;
• selbstständige Forschung original research;
• selbstständiger Freiberufler self-employed person;
• selbstständiger Gewerbetreibender independent businessman;
• selbstständiger Kaufmann established merchant;
• selbstständiges Land substantive nation;
• selbstständiges Patent independent patent;
• in selbstständiger Position sein to be in an established position;
• selbstständiger Schadenabschätzer independent adjuster;
• selbstständige Tätigkeit independent activities;
• selbstständiges Tätigkeitsgebiet free field of operations;
• selbstständiger Unternehmer independent contractor, self-employer;
• selbstständiger Vertrag independent contract.

независимый патент

Business: independent patent

Poulsen, Valdemar

SUBJECT AREA: Broadcasting, Electronics and information technology, Recording, Telecommunications

[br]

b. 23 November 1869 Copenhagen, Denmark

d. 23 July 1942 Gentofte, Denmark

[br]

Danish engineer who developed practical magnetic recording and the arc generator for continuous radio waves.

[br]

From an early age he was absorbed by phenomena of physics to the exclusion of all other subjects, including mathematics. When choosing his subjects for the final three years in Borgedydskolen in Christianshavn (Copenhagen) before university, he opted for languages and history. At the University of Copenhagen he embarked on the study of medicine in 1889, but broke it off and was apprenticed to the machine firm of A/S Frichs Eftf. in Aarhus. He was employed between 1893 and 1899 as a mechanic and assistant in the laboratory of the Copenhagen Telephone Company KTAS. Eventually he advanced to be Head of the line fault department. This suited his desire for experiment and measurement perfectly. After the invention of the telegraphone in 1898, he left the laboratory and with responsible business people he created Aktieselskabet Telegrafonen, Patent Poulsen in order to develop it further, together with Peder Oluf Pedersen (1874– 1941). Pedersen brought with him the mathematical background which eventually led to his professorship in electronic engineering in 1922.

The telegraphone was the basis for multinational industrial endeavours after it was demonstrated at the 1900 World's Exhibition in Paris. It must be said that its strength was also its weakness, because the telegraphone was unique in bringing sound recording and reproduction to the telephone field, but the lack of electronic amplifiers delayed its use outside this and the dictation fields (where headphones could be used) until the 1920s. However, commercial interest was great enough to provoke a number of court cases concerning patent infringement, in which Poulsen frequently figured as a witness.

In 1903–4 Poulsen and Pedersen developed the arc generator for continuous radio waves which was used worldwide for radio transmitters in competition with Marconi's spark-generating system. The inspiration for this work came from the research by William Duddell on the musical arc. Whereas Duddell had proposed the use of the oscillations generated in his electric arc for telegraphy in his 1901 UK patent, Poulsen contributed a chamber of hydrogen and a transverse magnetic field which increased the efficiency remarkably. He filed patent applications on these constructions from 1902 and the first publication in a scientific forum took place at the International Electrical Congress in St Louis, Missouri, in 1904.

In order to use continuous waves efficiently (the high frequency constituted a carrier), Poulsen developed both a modulator for telegraphy and a detector for the carrier wave. The modulator was such that even the more primitive spark-communication receivers could be used. Later Poulsen and Pedersen developed frequency-shift keying.

The Amalgamated Radio-Telegraph Company Ltd was launched in London in 1906, combining the developments of Poulsen and those of De Forest Wireless Telegraph Syndicate. Poulsen contributed his English and American patents. When this company was liquidated in 1908, its assets were taken over by Det Kontinentale Syndikat for Poulsen Radio Telegrafi, A/S in Copenhagen (liquidated 1930–1). Some of the patents had been sold to C.Lorenz AG in Berlin, which was very active.

The arc transmitting system was in use worldwide from about 1910 to 1925, and the power increased from 12 kW to 1,000 kW. In 1921 an exceptional transmitter rated at 1,800 kW was erected on Java for communications with the Netherlands. More than one thousand installations had been in use worldwide. The competing systems were initially spark transmitters (Marconi) and later rotary converters ( Westinghouse). Similar power was available from valve transmitters only much later.

From c. 1912 Poulsen did not contribute actively to further development. He led a life as a well-respected engineer and scientist and served on several committees. He had his private laboratory and made experiments in the composition of matter and certain resonance phenomena; however, nothing was published. It has recently been suggested that Poulsen could not have been unaware of Oberlin Smith's work and publication in 1888, but his extreme honesty in technical matters indicates that his development was indeed independent. In the case of the arc generator, Poulsen was always extremely frank about the inspiration he gained from earlier developers' work.

[br]

Bibliography

1899, British patent no. 8,961 (the first British telegraphone patent). 1903, British patent no. 15,599 (the first British arc-genera tor patent).

His scientific publications are few, but fundamental accounts of his contribution are: 1900, "Das Telegraphon", Ann. d. Physik 3:754–60; 1904, "System for producing continuous oscillations", Trans. Int. El. Congr. St. Louis, Vol. II, pp. 963–71.

Further Reading

A.Larsen, 1950, Telegrafonen og den Traadløse, Ingeniørvidenskabelige Skrifter no. 2, Copenhagen (provides a very complete, although somewhat confusing, account of Poulsen's contributions; a list of his patents is given on pp. 285–93).

F.K.Engel, 1990, Documents on the Invention of Magnetic Re cor ding in 1878, New York: Audio Engineering Society, reprint no. 2,914 (G2) (it is here that doubt is expressed about whether Poulsen's ideas were developed independently).

GB-N

Johnson, Eldridge Reeves

SUBJECT AREA: Recording

[br]

b. 18 February 1867 Wilmington, Delaware, USA

d. 14 November 1945 Moorestown, New Jersey, USA

[br]

American industrialist, founder and owner of the Victor Talking Machine Company; developer of many basic constructions in mechanical sound recording and the reproduction and manufacture of gramophone records.

[br]

He graduated from the Dover Academy (Delaware) in 1882 and was apprenticed in a machine-repair firm in Philadelphia and studied in evening classes at the Spring Garden Institute. In 1888 he took employment in a small Philadelphia machine shop owned by Andrew Scull, specializing in repair and bookbinding machinery. After travels in the western part of the US, in 1891 he became a partner in Scull \& Johnson, Manufacturing Machinists, and established a further company, the New Jersey Wire Stitching Machine Company. He bought out Andrew Scull's interest in October 1894 (the last instalment being paid in 1897) and became an independent general machinist. In 1896 he had perfected a spring motor for the Berliner flat-disc gramophone, and he started experimenting with a more direct method of recording in a spiral groove: that of cutting in wax. Co-operation with Berliner eventually led to the incorporation of the Victor Talking Machine Company in 1901. The innumerable court cases stemming from the fact that so many patents for various elements in sound recording and reproduction were in very many hands were brought to an end in 1903 when Johnson was material in establishing cross-licencing agreements between Victor, Columbia Graphophone and Edison to create what is known as a patent pool. Early on, Johnson had a thorough experience in all matters concerning the development and manufacture of both gramophones and records. He made and patented many major contributions in all these fields, and his approach was very business-like in that the contribution to cost of each part or process was always a decisive factor in his designs. This attitude was material in his consulting work for the sister company, the Gramophone Company, in London before it set up its own factories in 1910. He had quickly learned the advantages of advertising and of providing customers with durable equipment and records. This motivation was so strong that Johnson set up a research programme for determining the cause of wear in records. It turned out to depend on groove profile, and from 1911 one particular profile was adhered to and processes for transforming the grooves of valuable earlier records were developed. Without precise measuring instruments, he used the durability as the determining factor. Johnson withdrew more and more to the role of manager, and the Victor Talking Machine Company gained such a position in the market that the US anti-trust legislation was used against it. However, a generation change in the Board of Directors and certain erroneous decisions as to product line started a decline, and in February 1926 Johnson withdrew on extended sick leave: these changes led to the eventual sale of Victor. However, Victor survived due to the advent of radio and the electrification of replay equipment and became a part of Radio Corporation of America. In retirement Johnson took up various activities in the arts and sciences and financially supported several projects; his private yacht was used in 1933 in work with the Smithsonian Institution on a deep-sea hydrographie and fauna-collecting expedition near Puerto Rico.

[br]

Bibliography

Johnson's patents were many, and some were fundamental to the development of the gramophone, such as: US patent no. 650,843 (in particular a recording lathe); US patent nos. 655,556, 655,556 and 679,896 (soundboxes); US patent no. 681,918 (making the original conductive for electroplating); US patent no. 739,318 (shellac record with paper label).

Further Reading

Mrs E.R.Johnson, 1913, "Eldridge Reeves Johnson (1867–1945): Industrial pioneer", manuscript (an account of his early experience).

E.Hutto, Jr, "Emile Berliner, Eldridge Johnson, and the Victor Talking Machine Company", Journal of AES 25(10/11):666–73 (a good but brief account based on company information).

E.R.Fenimore Johnson, 1974, His Master's Voice was Eldridge R.Johnson, Milford, Del.

(a very personal biography by his only son).

GB-N

Bright, Sir Charles Tilston

SUBJECT AREA: Telecommunications

[br]

b. 8 June 1832 Wanstead, Essex, England

d. 3 May 1888 Abbey Wood, London, England

[br]

English telegraph engineer responsible for laying the first transatlantic cable.

[br]

At the age of 15 years Bright left the London Merchant Taylors' School to join the two-year-old Electric Telegraph Company. By 1851 he was in charge of the Birmingham telegraph station. After a short time as Assistant Engineer with the newly formed British Telegraph Company, he joined his brother (who was Manager) as Engineer-in-Chief of the English and Irish Magnetic Telegraph Company in Liverpool, for which he laid thousands of miles of underground cable and developed a number of innovations in telegraphy including a resistance box for locating cable faults and a two-tone bell system for signalling. In 1853 he was responsible for the first successful underwater cable between Scotland and Ireland. Three years later, with the American financier Cyrus Field and John Brett, he founded and was Engineer-in-chief of the Atlantic Telegraph Company, which aimed at laying a cable between Ireland and Newfoundland. After several unsuccessful attempts this was finally completed on 5 August 1858, Bright was knighted a month later, but the cable then failed! In 1860 Bright resigned from the Magnetic Telegraph Company to set up an independent consultancy with another engineer, Joseph Latimer Clark, with whom he invented an improved bituminous cable insulation. Two years later he supervised construction of a telegraph cable to India, and in 1865 a further attempt to lay an Atlantic cable using Brunel's new ship, the Great Eastern. This cable broke during laying, but in 1866 a new cable was at last successfully laid and the 1865 cable recovered and repaired. The year 1878 saw extension of the Atlantic cable system to the West Indies and the invention with his brother of a system of neighbourhood fire alarms and even an automatic fire alarm.

In 1861 Bright presented a paper to the British Association for the Advancement of Science on the need for electrical standards, leading to the creation of an organization that still exists in the 1990s. From 1865 until 1868 he was Liberal MP for Greenwich, and he later assisted with preparations for the 1881 Paris Exhibition.

[br]

Principal Honours and Distinctions

Knighted 1858. Légion d'honneur. First President, Société Internationale des Electriciens. President, Society of Telegraph Engineers \& Electricians (later the Institution of Electrical Engineers) 1887.

Bibliography

1852, British patent (resistance box).

1855, British patent no. 2,103 (two-tone bell system). 1878, British patent no. 3,801 (area fire alarms).

1878, British patent no. 596 (automatic fire alarm).

"The physical \& electrical effects of pressure \& temperature on submarine cable cores", Journal of the Institution of Electrical Engineers XVII (describes some of his investigations of cable characteristics).

Further Reading

C.Bright, 1898, Submarine Cables, Their History, Construction \& Working.

—1910, The Life Story of Sir Charles Tilston Bright, London: Constable \& Co.

KF

De Forest, Lee

SUBJECT AREA: Broadcasting, Electronics and information technology, Photography, film and optics, Recording, Telecommunications

[br]

b. 26 August 1873 Council Bluffs, Iowa, USA

d. 30 June 1961 Hollywood, California, USA

[br]

American electrical engineer and inventor principally known for his invention of the Audion, or triode, vacuum tube; also a pioneer of sound in the cinema.

[br]

De Forest was born into the family of a Congregational minister that moved to Alabama in 1879 when the father became President of a college for African-Americans; this was a position that led to the family's social ostracism by the white community. By the time he was 13 years old, De Forest was already a keen mechanical inventor, and in 1893, rejecting his father's plan for him to become a clergyman, he entered the Sheffield Scientific School of Yale University. Following his first degree, he went on to study the propagation of electromagnetic waves, gaining a PhD in physics in 1899 for his thesis on the "Reflection of Hertzian Waves from the Ends of Parallel Wires", probably the first US thesis in the field of radio.

He then joined the Western Electric Company in Chicago where he helped develop the infant technology of wireless, working his way up from a modest post in the production area to a position in the experimental laboratory. There, working alone after normal working hours, he developed a detector of electromagnetic waves based on an electrolytic device similar to that already invented by Fleming in England. Recognizing his talents, a number of financial backers enabled him to set up his own business in 1902 under the name of De Forest Wireless Telegraphy Company; he was soon demonstrating wireless telegraphy to interested parties and entering into competition with the American Marconi Company.

Despite the failure of this company because of fraud by his partners, he continued his experiments; in 1907, by adding a third electrode, a wire mesh, between the anode and cathode of the thermionic diode invented by Fleming in 1904, he was able to produce the amplifying device now known as the triode valve and achieve a sensitivity of radio-signal reception much greater than possible with the passive carborundum and electrolytic detectors hitherto available. Patented under the name Audion, this new vacuum device was soon successfully used for experimental broadcasts of music and speech in New York and Paris. The invention of the Audion has been described as the beginning of the electronic era. Although much development work was required before its full potential was realized, the Audion opened the way to progress in all areas of sound transmission, recording and reproduction. The patent was challenged by Fleming and it was not until 1943 that De Forest's claim was finally recognized.

Overcoming the near failure of his new company, the De Forest Radio Telephone Company, as well as unsuccessful charges of fraudulent promotion of the Audion, he continued to exploit the potential of his invention. By 1912 he had used transformer-coupling of several Audion stages to achieve high gain at radio frequencies, making long-distance communication a practical proposition, and had applied positive feedback from the Audion output anode to its input grid to realize a stable transmitter oscillator and modulator. These successes led to prolonged patent litigation with Edwin Armstrong and others, and he eventually sold the manufacturing rights, in retrospect often for a pittance.

During the early 1920s De Forest began a fruitful association with T.W.Case, who for around ten years had been working to perfect a moving-picture sound system. De Forest claimed to have had an interest in sound films as early as 1900, and Case now began to supply him with photoelectric cells and primitive sound cameras. He eventually devised a variable-density sound-on-film system utilizing a glow-discharge modulator, the Photion. By 1926 De Forest's Phonofilm had been successfully demonstrated in over fifty theatres and this system became the basis of Movietone. Though his ideas were on the right lines, the technology was insufficiently developed and it was left to others to produce a system acceptable to the film industry. However, De Forest had played a key role in transforming the nature of the film industry; within a space of five years the production of silent films had all but ceased.

In the following decade De Forest applied the Audion to the development of medical diathermy. Finally, after spending most of his working life as an independent inventor and entrepreneur, he worked for a time during the Second World War at the Bell Telephone Laboratories on military applications of electronics.

[br]

Principal Honours and Distinctions

Institute of Electronic and Radio Engineers Medal of Honour 1922. President, Institute of Electronic and Radio Engineers 1930. Institute of Electrical and Electronics Engineers Edison Medal 1946.

Bibliography

1904, "Electrolytic detectors", Electrician 54:94 (describes the electrolytic detector). 1907, US patent no. 841,387 (the Audion).

1950, Father of Radio, Chicago: WIlcox \& Follett (autobiography).

De Forest gave his own account of the development of his sound-on-film system in a series of articles: 1923. "The Phonofilm", Transactions of the Society of Motion Picture Engineers 16 (May): 61–75; 1924. "Phonofilm progress", Transactions of the Society of Motion Picture Engineers 20:17–19; 1927, "Recent developments in the Phonofilm", Transactions of the Society of Motion Picture Engineers 27:64–76; 1941, "Pioneering in talking pictures", Journal of the Society of Motion Picture Engineers 36 (January): 41–9.

Further Reading

G.Carneal, 1930, A Conqueror of Space (biography).

I.Levine, 1964, Electronics Pioneer, Lee De Forest (biography).

E.I.Sponable, 1947, "Historical development of sound films", Journal of the Society of Motion Picture Engineers 48 (April): 275–303 (an authoritative account of De Forest's sound-film work, by Case's assistant).

W.R.McLaurin, 1949, Invention and Innovation in the Radio Industry.

C.F.Booth, 1955, "Fleming and De Forest. An appreciation", in Thermionic Valves 1904– 1954, IEE.

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

KF / JW

Kilby, Jack St Clair

SUBJECT AREA: Electronics and information technology

[br]

b. 8 November 1923 Jefferson City, Missouri, USA

[br]

American engineer who filed the first patents for micro-electronic (integrated) circuits.

[br]

Kilby spent most of his childhood in Great Bend, Kansas, where he often accompanied his father, an electrical power engineer, on his maintenance rounds. Working in the blizzard of 1937, his father borrowed a "ham" radio, and this fired Jack to study for his amateur licence (W9GTY) and to construct his own equipment while still a student at Great Bend High School. In 1941 he entered the University of Illinois, but four months later, after the attack on Pearl Harbor, he was enlisted in the US Army and found himself working in a radio repair workshop in India. When the war ended he returned to his studies, obtaining his BSEE from Illinois in 1947 and his MSEE from the University of Wisconsin. He then joined Centralab, a small electronics firm in Milwaukee owned by Globe-Union. There he filed twelve patents, including some for reduced titanate capacitors and for Steatite-packing of transistors, and developed a transistorized hearing-aid. During this period he also attended a course on transistors at Bell Laboratories. In May 1958, concerned to gain experience in the field of number processing, he joined Texas Instruments in Dallas. Shortly afterwards, while working alone during the factory vacation, he conceived the idea of making monolithic, or integrated, circuits by diffusing impurities into a silicon substrate to create P-N junctions. Within less than a month he had produced a complete oscillator on a chip to prove that the technology was feasible, and the following year at the 1ERE Show he demonstrated a germanium integrated-circuit flip-flop. Initially he was granted a patent for the idea, but eventually, after protracted litigation, priority was awarded to Robert Noyce of Fairchild. In 1965 he was commissioned by Patrick Haggerty, the Chief Executive of Texas Instruments, to make a pocket calculator based on integrated circuits, and on 14 April 1971 the world's first such device, the Pocketronic, was launched onto the market. Costing $150 (and weighing some 2½ lb or 1.1 kg), it was an instant success and in 1972 some 5 million calculators were sold worldwide. He left Texas Instruments in November 1970 to become an independent consultant and inventor, working on, amongst other things, methods of deriving electricity from sunlight.

[br]

Principal Honours and Distinctions

Franklin Institute Stuart Ballantine Medal 1966. Institute of Electrical and Electronics Engineers David Sarnoff Award 1966; Cledo Brunetti Award (jointly with Noyce) 1978; Medal of Honour 1986. National Academy of Engineering 1967. National Science Medal 1969. National Inventors Hall of Fame 1982. Honorary DEng Miami 1982, Rochester 1986. Honorary DSc Wisconsin 1988. Distinguished Professor, Texas A \& M University.

Bibliography

6 February 1959, US patent no. 3,138,743 (the first integrated circuit (IC); initially granted June 1964).

US patent no. 3,819,921 (the Pocketronic calculator).

Further Reading

T.R.Reid, 1984, Microchip. The Story of a Revolution and the Men Who Made It, London: Pan Books (for the background to the development of the integrated circuit). H.Queisser, 1988, Conquest of the Microchip, Cambridge, Mass.: Harvard University Press.

KF

Need, Samuel

SUBJECT AREA: Textiles

[br]

b. 1718

d. 14 April 1781 Bread Street, Cheapside, London, England

[br]

English manufacturer of hosiery who helped to finance Arkwright's spinning machine and early cotton mills.

[br]

Samuel Need was apprenticed as a framework knitter and entered the hosiery trade c. 1742. He was a Dissenter and later became an Independent Congregationalist. He married Elizabeth Gibson of Hacking, Middlesex, who survived him and died in 1781. He had a warehouse in Nottingham, where he was made a burgess in 1739–40. In 1747 he bought a mill there and had a house adjoining it, but in 1777 he bought an estate at Arnold, outside the city. From about 1759 he supported Jedediah Strutt and William Woollat in their development of Strutt's invention of the rib attachment to the knitting machine. Need became a partner with Strutt in 1762 over the patent and then they shared a joint hosiery business. When Arkwright sought financial assistance from Ichabod and John Wright, the Nottingham bankers, to develop his spinning mill in that town, the Wrights turned him over to Samuel Need. Need, having profited so much from the successful patent with Strutt, was ready to exploit another; on 19 January 1770 Need and Strutt, on payment of £500, became co-partners with Arkwright, Smalley and Thornley for the remainder of Arkwright's patent. In Need, Arkwright had secured the patronage of the leading hosier in Nottingham. Need was leader of the Hosiers' Federation in 1779 when the framework knitters petitioned Parliament to better their conditions. He gave evidence against the workers' demands and, when their bill failed, the Nottingham workers attacked first his Nottingham house and then the one at Arnold.

Need was to remain a partner with Arkwright until his death in 1781. He was involved in die mill at Cromford and also with some later ones, such as the Birkacre mill near Chorley, Lancashire, in 1777. He made a fortune and died at his home in London.

[br]

Further Reading

M.L.Walker, 1963, A History of the Family of Need of Arnold, Nottinghamshire, London (a good biography).

R.S.Fitton, 1989, The Arkwrights, Spinners of Fortune, Manchester (covers Need's relationship with Arkwright).

R.S.Fitton and A.P.Wadsworth, 1958, The Strutts and the Arkwrights, 1758–1830, Manchester.

S.D.Chapman, 1967, The Early Factory Masters, Newton Abbot (describes his wider contacts with the Midlands hosiery industry).

RLH

Blumlein, Alan Dower

SUBJECT AREA: Aerospace, Broadcasting, Electronics and information technology, Photography, film and optics, Recording, Telecommunications

[br]

b. 29 June 1903 Hampstead, London, England

d. 7 June 1942

[br]

English electronics engineer, developer of telephone equipment, highly linear electromechanical recording and reproduction equipment, stereo techniques, video and radar technology.

[br]

He was a very bright scholar and received a BSc in electrical technology from City and Guilds College in 1923. He joined International Western Electric (later to become Standard Telephone and Cables) in 1924 after a period as an instructor/demonstrator at City and Guilds. He was instrumental in the design of telephone measuring equipment and in international committee work for standards for long-distance telephony.

From 1929 Blumlein was employed by the Columbia Graphophone Company to develop an electric recording cutterhead that would be independent of Western Electric's patents for the system developed by Maxfield and Harrison. He attacked the problems in a most systematic fashion, and within a year he had developed a moving-coil cutterhead that was much more linear than the iron-cored systems known at the time. Eventually Blumlein designed a complete line of recording equipment, from microphone and through-power amplifiers. The design was used by Columbia; after the merger with the Gramophone Company in 1931 to form Electrical and Musical Industries Ltd (later known as EMI) it became the company standard, certainly for coarse-groove records, until c.1950.

Blumlein became interested in stereophony (binaural sound), and developed and demonstrated a complete line of equipment, from correctly placed microphones via two-channel records and stereo pick-ups to correctly placed loudspeakers. The advent of silent surfaces of vinyl records made this approach commercial from the late 1950s. His approach was independent and quite different from that of A.C. Keller.

His extreme facility for creating innovative solutions to electronic problems was used in EMI's development from 1934 to 1938 of the electronic television system, which became the BBC standard of 405 lines after the Second World War, when television broadcasting again became possible. Independent of official requirements, EMI developed a 60 MHz radar system and Blumlein was involved in the development of a centimetric radar and display system. It was during testing of this aircraft mounted equipment that he was killed in a crash.

[br]

Bibliography

Blumlein was inventor or co-inventor of well over 120 patents, a complete list of which is to be found in Burns (1992; see below). The major sound-recording achievements are documented by British patent nos. 350,954, 350,998, 363,627 (highly linear cutterhead, 1930) and 394,325 (reads like a textbook on stereo technology, 1931).

Further Reading

The definitive biography of Blumlein has not yet been written; the material seems to have been collected, but is not yet available. However, R.W.Burns, 1992, "A.D.Blumlein, engineer extraordinary", Engineering Science and Education Journal (February): 19– 33 is a thorough account. Also B.J.Benzimra, 1967, "A.D. Blumlein: an electronics genius", Electronics \& Power (June): 218–24 provides an interesting summary.

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Verletzung

Verletzung f 1. RECHT violation, breach infringement (Urheberrecht); 2. PAT infringement, violation; 3. PERS injury, harm (Körper) • in Verletzung von GEN in violation of

* * *

f 1. < Recht> violation, breach Urheberrecht infringement; 2. < Patent> infringement, violation; 3. < Person> Körper injury, harm ■ in Verletzung von < Geschäft> in violation of

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: von allen anderen Einwirkungen unabhängige Verletzung

< Versich> Krankenversicherung injury independent of all other means

* * *

Verletzung
injury, wound, hurt, violence, (Beschädigung) damage, (Überschreitung) infraction, (Vertrag) violation, transgression, breach;
• unter Verletzung von in contravention of;
• einklagbare Verletzung private injury;
• geringfügige Verletzungen minor injuries;
• offenkundige Verletzung public infringement;
• schadenersatzerhöhende Verletzungen aggravation of the disability;
• schwere Verletzung serious injury;
• tödliche Verletzung fatal injury;
• unfallbedingte Verletzung sudden or violent injury;
• Verletzung der Amtspflicht official misconduct, malfeasance, malversation;
• Verletzung der vorvertraglichen Anzeigepflicht (Versicherung) non-disclosure;
• Verletzung des Berufsgeheimnisses breach of professional secrecy;
• Verletzung der Bestimmungen des Kartellgesetzes Antitrust Act Violation (US);
• Verletzung der Börsenvorschriften trading violations;
• Verletzung der Datensicherheit (Internet) infringement of data security;
• Verletzung der Garantiehaftung break of warranty;
• Verletzung eines Gebrauchsmusters infringement of registered design (Br.);
• Verletzung der Geheimhaltungspflicht breach of confidence;
• Verletzung eines Gesetzes infraction (breach) of a law;
• [anhaltende] Verletzung der bürgerlichen Grundrechte [persistent] violation of basic rights (the rights of a citizen);
• Verletzung des gemeinschaftlichen Grundrechts auf gleiches Entgelt infringement of the basic Community right to equal pay;
• Verletzung der Intimsphäre invasion of s. one’s privacy, violation of privacy;
• Verletzung des Luftraums violation of airspace;
• Verletzung eines Patents infringement of a patent right;
• Verletzung von Pflichten (Europäischer Gerichtshof) non-compliance with obligations;
• Verletzung der zugesicherten Qualitätsgarantie quality-assurance violation;
• Verletzung von jds. Rechten encroachment on s. one’s rights;
• Verletzung der Sorgfaltspflicht lack of care;
• Verletzung der gesetzlich vorgeschriebenen Sorgfaltspflicht negligence in law, statutory negligence (US);
• Verletzung der Treuepflicht breach of trust;
• Verletzung des Umweltrechts violation of environmental laws;
• Verletzung durch einen Unfall accidental injury, injury caused by accident;
• vorsätzliche Verletzung der Unterhaltspflicht wilful neglect to provide reasonable maintenance (Br.), nonsupport (US);
• Verletzung des Urheberrechts infringement of copyright;
• Verletzung einer Verkehrsvorschrift moving (Br.) (traffic, US) violation;
• Verletzung eines Vertrages infringement (violation, breaking) of a contract;
• Verletzung der Vertragsautonomie impairment of contracts;
• Verletzung der Vorfahrt violation of the right of way;
• Verletzung von Warenzeichenrechten infringement of trademarks;
• Verletzung einer vertraglichen Zusicherung breach of warranty;
• Verletzung eines Vertrages feststellen to set up the breach.

Harwood, John

SUBJECT AREA: Horology

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b. 1893 Bolton, England

d. 9 August 1964

[br]

English watchmaker, inventor and producer of the first commercial self-winding wrist watch.

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John Harwood served an apprenticeship as a watch repairer in Bolton, and after service in the First World War he obtained a post with a firm of jewellers in Douglas, Isle of Man. He became interested in the self-winding wrist watch, not because of the convenience of not having to wind it, but because of its potential to keep the mainspring fully wound and to exclude dust and moisture from the watch movement. His experience at the bench had taught him that these were the most common factors to affect adversely the reliability of watches. Completely unaware of previous work in this area, in 1922 he started experimenting and two years later he had produced a serviceable model for which he was granted a patent in 1924. The watch operated on the pedometer principle, the mainspring being wound by a pivoted weight that oscillated in the watch case as a result of the motion of the arm. The hands of his watch were set by rotating the bezel surrounding the dial, dispensing with the usual winding/hand-setting stem which allowed dust and moisture to enter the watch case. He took the watch to Switzerland, but he was unable to persuade the watchmaking firms to produce it until he had secured independent finance to cover the cost of tooling. The Harwood Self-Winding Watch Company Ltd was set up in 1928 to market the watches, but although several thousand were produced the company became a victim of the slump and closed down in 1932. The first practical self-winding watch also operated on the pedometer principle and is attributed to Abraham-Louis Perrellet (1770). The method was refined by Breguet in France and by Recordon, who patented the device in England, but it proved troublesome and went out of fashion. There was a brief revival of interest in self-winding watches towards the end of the nineteenth century, but they never achieved great popularity until after the Second World War, when they used either self-winding mechanisms similar to that devised by Harwood or weights which rotated in the case.

[br]

Principal Honours and Distinctions

British Horological Institute Gold Medal 1957.

Bibliography

1 September 1924, Swiss patent no. 106,582.

Further Reading

A.Chapuis and E.Jaquet, 1956, The History of the Self-Winding Watch, London (provides general information).

"How the automatic wrist watch was invented", 1957, Horological Journal 99:612–61 (for specific information).

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