Revision as of 17:51, 17 August 2019 edit Spinningspark (talk \| contribs) 89,216 edits →History: copyedit new material, fix break in text-source integrity, convert to established reference style ← Previous edit		Revision as of 18:04, 17 August 2019 edit undo Spinningspark (talk \| contribs) 89,216 edits →History: removing some uncited claims in recent addition. Harford does not give the wavelength used. Levy and Cohen do not discuss the magnetron. Next edit →
Line 152: [[Warren P. Mason]] was the first to investigate the possibility of distributed element circuits, and filed a patent<ref>Mason (1930)</ref> in 1927 for a coaxial filter designed by this method. Mason and Sykes published the definitive paper on the method in 1937. Mason was also the first to suggest a distributed element acoustic filter in his 1927 doctoral thesis, and a distributed element mechanical filter in a patent<ref>Mason (1961)</ref> filed in 1941. Mason's work was concerned with the coaxial form and other conducting wires, although much of it could also be adapted for waveguide. The acoustic work had come first, and Mason's colleagues in the [[Bell Labs]] radio department asked him to assist with coaxial and waveguide filters.<ref>{{multiref\|Johnson ''et al.'' (1971), p. 155\|Fagen & Millman, p. 108\|Levy & Cohn, p. 1055\|Polkinghorn (1973)}}</ref> Before [[World War II]], there was little demand for distributed element circuits; the frequencies used for radio transmissions were lower than the point at which distributed elements became advantageous. Lower frequencies had a greater range, a primary consideration for [[Broadcasting\|broadcast]] purposes. These frequencies require long ~~antennas~~antennae for efficient operation, and this led to work on higher-frequency systems. A key breakthrough was the 1940 introduction of the [[cavity magnetron]] which operated atin the ~~10 cm~~microwave ~~(3 GHz)~~band.<ref>Harford</ref> A surge in distributed element filter development followed, filters being an essential component of radars. As ~~magnetron use spread, the~~The signal loss in coaxial cables led to the first widespread use of waveguide, and the filter technology was extended from the coaxial ___domain into the waveguide ___domain.<ref>Levy & Cohn, p. 1055</ref> The wartime work was mostly unpublished until after the war for security reasons, which made it difficult to ascertain who was responsible for each development. An important centre for this research was the [[MIT Radiation Laboratory]] (Rad Lab), but work was also done elsewhere in the US and Britain. The Rad Lab work was published<ref>Fano & Lawson (1948)</ref> by Fano and Lawson.<ref>Levy & Cohn, p. 1055</ref> Another wartime development was the hybrid ring. This work was carried out at [[Bell Labs]], and was published<ref>Tyrrell (1947)</ref> after the war by W. A. Tyrrell. Tyrrell describes hybrid rings implemented in waveguide, and analyses them in terms of the well-known waveguide [[magic tee]]. Other researchers<ref>{{multiref\|Sheingold & Morita (1953)\|Albanese & Peyser (1958)}}</ref> soon published coaxial versions of this device.<ref>Ahn, p. 3</ref>

Distributed-element circuit: Difference between revisions