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Robert Watson-Watt

January 07, 2023

Sir Robert Alexander Watson Watt KCB FRS FRAeS (13 April 1892 – 5 December 1973) was a Scottish pioneer of radio direction finding and radar technology.[2]

Sir

Robert Watson-Watt

KCB FRS FRAeS
Born
Robert Alexander Watson

(1892-04-13)13 April 1892
Brechin, Angus, Scotland
Died5 December 1973(1973-12-05) (aged 81)
Inverness, Scotland
Known forRadar
Awards

Watt began his career in radio physics with a job at the Met Office, where he began looking for accurate ways to track thunderstorms using the radio signals given off by lightning. This led to the 1920s development of a system later known as high-frequency direction finding (HFDF or "huff-duff"). Although well publicized at the time, the system's enormous military potential was not developed until the late 1930s. Huff-duff allowed operators to determine the location of an enemy radio in seconds and it became a major part of the network of systems that helped defeat the threat of German U-boats during World War II. It is estimated that huff-duff was used in about a quarter of all attacks on U-boats.

In 1935 Watt was asked to comment on reports of a German death ray based on radio. Watt and his assistant Arnold Frederic Wilkins quickly determined it was not possible, but Wilkins suggested using radio signals to locate aircraft at long distances. This led to a February 1935 demonstration where signals from a BBC short-wave transmitter were bounced off a Handley Page Heyford aircraft.[2][3] Watt led the development of a practical version of this device, which entered service in 1938 under the code name Chain Home. This system provided the vital advance information that helped the Royal Air Force win the Battle of Britain.[1][4]

After the success of his invention, Watson Watt was sent to the US in 1941 to advise on air defence after Japan's attack on Pearl Harbor. He returned and continued to lead radar development for the War Office and Ministry of Supply. He was elected a Fellow of the Royal Society in 1941, was given a knighthood in 1942 and was awarded the US Medal for Merit in 1946.

Early years

Watson-Watt [a][5] was born in Brechin, Angus, Scotland, on 13 April 1892. He claimed to be a descendant of James Watt, the famous engineer and inventor of the practical steam engine, but no evidence of any family relationship has been found.[6] After attending Damacre Primary School and Brechin High School,[7] he was accepted to University College, Dundee (then part of the University of St Andrews and which became Queen's College, Dundee in 1954 and then the University of Dundee in 1967). Watson-Watt had a successful time as a student, winning the Carnelley Prize for Chemistry and a class medal for Ordinary Natural Philosophy in 1910.[8]

He graduated with a BSc in engineering in 1912, and was offered an assistantship by Professor William Peddie,[9] the holder of the Chair of Physics at University College, Dundee from 1907 to 1942. It was Peddie who encouraged Watson-Watt to study radio, or "wireless telegraphy" as it was then known, and who took him through what was effectively a postgraduate class on the physics of radio frequency oscillators and wave propagation. At the start of the Great War Watson-Watt was working as an assistant in the college's Engineering Department.[10]

Early experiments

In 1916 Watson-Watt wanted a job with the War Office, but nothing obvious was available in communications. Instead he joined the Meteorological Office, which was interested in his ideas on the use of radio for the detection of thunderstorms. Lightning gives off a radio signal as it ionizes the air, and his goal was to detect this signal to warn pilots of approaching thunderstorms. The signal occurs across a wide range of frequencies, and could be easily detected and amplified by naval longwave sets. In fact, lightning was a major problem for communications at these common wavelengths.[11]

His early experiments were successful in detecting the signal and he quickly proved to be able to do so at ranges up to 2,500 km. Location was determined by rotating a loop antenna to maximise (or minimise) the signal, thus "pointing" to the storm. The strikes were so fleeting that it was very difficult to turn the antenna in time to positively locate one. Instead, the operator would listen to many strikes and develop a rough average location.[11]

At first, he worked at the Wireless Station of Air Ministry Meteorological Office in Aldershot, Hampshire. In 1924 when the War Department gave notice that they wished to reclaim their Aldershot site, he moved to Ditton Park near Slough, Berkshire. The National Physical Laboratory (NPL) was already using this site and had two main devices that would prove pivotal to his work.[11]

The first was an Adcock antenna, an arrangement of four masts that allowed the direction of a signal to be detected through phase differences. Using pairs of these antennas positioned at right angles, one could make a simultaneous measurement of the lightning's direction on two axes. Displaying the fleeting signals was a problem. This was solved by the second device, the WE-224 oscilloscope, recently acquired from Bell Labs. By feeding the signals from the two antennae into the X and Y channels of the oscilloscope, a single strike caused the appearance of a line on the display, indicating the direction of the strike. The scope's relatively "slow" phosphor only allowed the signal to be read long after the strike had occurred.[12] Watt's new system was being used in 1926 and was the topic of an extensive paper by Watson-Watt and Herd.[13]

The Met and NPL radio teams were amalgamated in 1927 to form the Radio Research Station with Watson-Watt as director. Continuing research throughout, the teams had become interested in the causes of "static" radio signals and found that much could be explained by distant signals located over the horizon being reflected off the upper atmosphere. This was the first direct indication of the reality of the Heaviside layer, proposed earlier, but at this time largely dismissed by engineers. To determine the altitude of the layer, Watt, Appleton and others developed the 'squegger' to develop a 'time base' display, which would cause the oscilloscope's dot to move smoothly across the display at very high speed. By timing the squegger so that the dot arrived at the far end of the display at the same time as expected signals reflected off the Heaviside layer, the altitude of the layer could be determined. This time-base circuit was key to the development of radar.[14] After a further reorganization in 1933, Watt became Superintendent of the Radio Department of NPL in Teddington.[citation needed]

RADAR

The air defence problem

During the First World War, the Germans had used Zeppelins as long-range bombers over Britain and defences had struggled to counter the threat. Since that time, aircraft capabilities had improved considerably and the prospect of widespread aerial bombardment of civilian areas was causing the government anxiety. Heavy bombers were now able to approach at altitudes that anti-aircraft guns of the day were unable to reach.[15] With enemy airfields across the English Channel potentially only 20 minutes' flying-time away, bombers would have dropped their bombs and be returning to base before any intercepting fighters could get to altitude. The only answer seemed to be to have standing patrols of fighters in the air, but with the limited cruising time of a fighter, this would require a huge air force. An alternative solution was urgently needed and, in 1934, the Air Ministry set up a committee, the CSSAD (Committee for the Scientific Survey of Air Defence), chaired by Sir Henry Tizard to find ways to improve air defence in the UK.[citation needed]

Rumours that Nazi Germany had developed a "death ray" that was capable of destroying towns, cities and people using radio waves, were given attention in January 1935 by Harry Wimperis, Director of Scientific Research at the Air Ministry. He asked Watson-Watt about the possibility of building their version of a death-ray, specifically to be used against aircraft.[3] Watson-Watt quickly returned a calculation carried out by his young colleague, Arnold Wilkins, showing that such a device was impossible to construct and fears of a Nazi version soon vanished. He also mentioned in the same report a suggestion that was originally made to him by Wilkins, who had recently heard of aircraft disturbing shortwave communications, that radio waves might be capable of detecting aircraft, "Meanwhile, attention is being turned to the still difficult, but less unpromising, problem of radio detection and numerical considerations on the method of detection by reflected radio waves will be submitted when required". Wilkins's idea, checked by Watt, was promptly presented by Tizard to the CSSAD on 28 January 1935.[16]

Aircraft detection and location

 
Memorial at the Daventry site of the first successful RADAR experiments. 52°11′46″N 1°03′00″W / 52.195982°N 1.050121°W / 52.195982; -1.050121
 
Closeup of memorial plaque
 
The first workable radar unit constructed by Robert Watson Watt and his team

On 12 February 1935, Watson-Watt sent the secret memo of the proposed system to the Air Ministry, Detection and location of aircraft by radio methods. Although not as exciting as a death-ray, the concept clearly had potential, but the Air Ministry, before giving funding, asked for a demonstration proving that radio waves could be reflected by an aircraft.[17] This was ready by 26 February and consisted of two receiving antennae located about 6 miles (9.7 km) away from one of the BBC's shortwave broadcast stations at Daventry. The two antennae were phased such that signals travelling directly from the station cancelled themselves out, but signals arriving from other angles were admitted, thereby deflecting the trace on a CRT indicator (passive radar).[18] Such was the secrecy of this test that only three people witnessed it: Watson-Watt, his colleague Arnold Wilkins, and a single member of the committee, A. P. Rowe. The demonstration was a success: on several occasions, the receiver showed a clear return signal from a Handley Page Heyford bomber flown around the site. Prime Minister Stanley Baldwin was kept quietly informed of radar progress. On 2 April 1935, Watson-Watt received a patent on a radio device for detecting and locating an aircraft.[3]

In mid-May 1935, Wilkins left the Radio Research Station with a small party, including Edward George Bowen, to start further research at Orford Ness, an isolated peninsula on the Suffolk coast of the North Sea. By June, they were detecting aircraft at a distance of 16 mi (26 km), which was enough for scientists and engineers to stop all work on competing sound-based detection systems. By the end of the year, the range was up to 60 mi (97 km), at which point, plans were made in December to set up five stations covering the approaches to London.[citation needed]

One of these stations was to be located on the coast near Orford Ness, and Bawdsey Manor was selected to become the main centre for all radar research. To put a radar defence in place as quickly as possible, Watson-Watt and his team created devices using existing components, rather than creating new components for the project, and the team did not take additional time to refine and improve the devices. So long as the prototype radars were in workable condition, they were put into production.[19] They conducted "full scale" tests of a fixed radar radio tower system, attempting to detect an incoming bomber by radio signals for interception by a fighter.[19][20] The tests were a complete failure, with the fighter only seeing the bomber after it had passed its target. The problem was not the radar but the flow of information from trackers from the Observer Corps to the fighters, which took many steps and was very slow. Henry Tizard, Patrick Blackett, and Hugh Dowding immediately set to work on this problem, designing a 'command and control air defence reporting system' with several layers of reporting that were eventually sent to a single large room for mapping. Observers watching the maps would then tell the fighters what to do via direct communications.[19]

 
Radar coverage along the UK coast, 1939–1940

By 1937, the first three stations were ready and the associated system was put to the test. The results were encouraging, and the government immediately commissioned construction of 17 additional stations. This became Chain Home, the array of fixed radar towers on the east and south coasts of England.[19][20] By the start of World War II, 19 were ready for the Battle of Britain, and by the end of the war, over 50 had been built. The Germans were aware of the construction of Chain Home but were not sure of its purpose. They tested their theories with a flight of the Zeppelin LZ 130 but concluded the stations were a new long-range naval communications system.[citation needed]

As early as 1936, it was realized that the Luftwaffe would turn to night bombing if the day campaign did not go well. Watson-Watt had put another of the staff from the Radio Research Station, Edward Bowen, in charge of developing a radar that could be carried by a fighter. Night-time visual detection of a bomber was good to about 300 m and the existing Chain Home systems simply did not have the accuracy needed to get the fighters that close. Bowen decided that an airborne radar should not exceed 90 kg (200 lb) in weight or 8 ft³ (230 L) in volume, and should require no more than 500 watts of power. To reduce the drag of the antennae, the operating wavelength could not be much greater than one metre, difficult for the day's electronics. However, Airborne Interception (AI), was perfected by 1940 and was instrumental in eventually ending The Blitz of 1941. Watson-Watt justified his choice of a non-optimal frequency for his radar, with his oft-quoted "cult of the imperfect", which he stated as "Give them the third-best to go on with; the second-best comes too late, [and] the best never comes".[citation needed]

Civil Service trade union activities

Between 1934 and 1936, Watson-Watt was president of the Institution of Professional Civil Servants, now a part of Prospect, the "union for professionals". The union speculates that at this time he was involved in campaigning for an improvement in pay for Air Ministry staff.[21]

Contribution to Second World War

 
Sir Robert Alexander Watson-Watt, ca. 1944

In his English History 1914–1945, the historian A. J. P. Taylor paid the highest of praise to Watson-Watt, Sir Henry Tizard and their associates who developed radar, crediting them with being fundamental to victory in the Second World War.[22]

In July 1938, Watson-Watt left Bawdsey Manor and took up the post of Director of Communications Development (DCD-RAE). In 1939, Sir George Lee took over the job of DCD and Watson-Watt became Scientific Advisor on Telecommunications (SAT) to the Ministry of Aircraft Production, travelling to the US in 1941 to advise them on the severe inadequacies of their air defence, illustrated by the Pearl Harbor attack. He was knighted by George VI in 1942 and received the US Medal for Merit in 1946.[23][24]

 
Sir Robert descends from a plinth in Trafalgar Square, London in 1961 after speaking at a rally protesting at the spread of nuclear weapons

Ten years after his knighthood, Watson-Watt was awarded £50,000 by the UK government for his contributions in the development of radar. He established a practice as a consulting engineer. In the 1950s, he moved to Canada and later he lived in the US, where he published Three Steps to Victory in 1958. Around 1958, he appeared as a mystery challenger on the American television programme To Tell The Truth. In 1956, Watson-Watt reportedly was pulled over for speeding in Canada by a radar gun-toting policeman. His remark was, "Had I known what you were going to do with it I would never have invented it!".[2] He wrote an ironic poem ("A Rough Justice") afterwards,

Pity Sir Robert Watson-Watt,
strange target of this radar plot

And thus, with others I can mention,
the victim of his own invention.

His magical all-seeing eye
enabled cloud-bound planes to fly

but now by some ironic twist
it spots the speeding motorist

and bites, no doubt with legal wit,
the hand that once created it.

...[25]

Honours

Legacy

 
Memorial to Watson-Watt at Brechin in Angus, Scotland
 
Memorial to the Birth of Radar, at Stowe Nine Churches, naming Watson-Watt and Arnold Wilkins

On 3 September 2014 a statue of Sir Robert Watson-Watt was unveiled in Brechin by the Princess Royal.[29] One day later, the BBC Two drama Castles in the Sky, aired with Eddie Izzard in the role of Watson Watt.[30]

A collection of some of the correspondence and papers of Watson-Watt is held by the National Library of Scotland.[31] A collection of papers relating to Watson-Watt is also held by Archive Services at the University of Dundee.[32]

A briefing facility at RAF Boulmer has been named the Watson-Watt auditorium in his honour.[citation needed]

Business and financial life

Watson-Watt had a problematic business and financial life.[33]

Family life

Watson-Watt was married[34] on 20 July 1916 in Hammersmith, London to Margaret Robertson (d. 1988), the daughter of a draughtsman; they later divorced and he remarried in 1952 in Canada.[35] His second wife was Jean Wilkinson, who died in 1964.[36] He returned to Scotland in the 1960s.[2]

In 1966, at the age of 74, he proposed to Dame Katherine Trefusis Forbes, who was 67 years old at the time and had also played a significant role in the Battle of Britain as the founding Air Commander of the Women's Auxiliary Air Force, which supplied the radar-room operatives. They lived together in London in the winter, and at "The Observatory": Trefusis Forbes' summer home in Pitlochry, Perthshire, during the warmer months. They remained together until her death in 1971. Watson-Watt died in 1973, aged 81, in Inverness. They are buried together in the churchyard of the Episcopal Church of the Holy Trinity at Pitlochry.[2]

See also

Notes

  1. ^ the hyphenated name is used herein for consistency, although he did not adopt it until 1942

References

  1. ^ a b Ratcliffe, J. A. (1975). "Robert Alexander Watson-Watt 13 April 1892 -- 5 December 1973". Biographical Memoirs of Fellows of the Royal Society. 21: 548–568. doi:10.1098/rsbm.1975.0018. S2CID 72585933.
  2. ^ a b c d e "Making waves: Robert Watson Watt, the pioneer of radar". BBC. 16 February 2017. from the original on 28 February 2017.
  3. ^ a b c "British Patent for Radar System for Air Defense Granted to Robert Watson Watt". American Physical Society. 17 February 2017. from the original on 2 December 2016.
  4. ^ Watson-Watt, Sir Robert; The Pulse of Radar, Dial Press, 1959
  5. ^ London Gazette Issue 35618 published on 3 July 1942. Page 39
  6. ^ Nicoll, Steve (July 2017). "Robert Alexander Watson Watt". Britain at War: 76.
  7. ^ "Sir Robert Watson-Watt". Dick Barrett. from the original on 5 March 2008. Retrieved 26 February 2008.
  8. ^ "100 years ago..." Archives Records and Artefacts at the University of Dundee. from the original on 4 March 2016. Retrieved 15 December 2015.
  9. ^ Allen, H. S. (1946). "Prof. William Peddie". Nature. 158 (4002): 50–51. Bibcode:1946Natur.158...50A. doi:10.1038/158050b0.
  10. ^ Shafe, Michael (1982). University Education in Dundee 1881–1981: A Pictorial History. Dundee: University of Dundee. pp. 58, 75 and 88.
  11. ^ a b c Brown 1999, p. 45.
  12. ^ Brown 1999, p. 46.
  13. ^ R. A. Watt and J. F. Herd, "An instantaneous direct-reading radiogoniometer" 2 February 2014 at the Wayback Machine, Journal of the Institution of Electrical Engineers, Volume 64 (February 1926), pp. 611–622.
  14. ^ O. S. Puckle, "Time Bases, Their Design and Development", Chapman & Hall, 1943
  15. ^ Evans, R.J. (18 September 2008). . Lecture transcript. Gresham College. Archived from the original on 17 November 2010. Retrieved 16 August 2009.
  16. ^ Buderi, Robert (1996). The Invention That Changed the World: How a Small Group of Radar Pioneers Won the Second World War and Launched a Technical Revolution (1998 ed.). Simon & Schuster. p. 55. ISBN 978-0-684-83529-7.
  17. ^ "Robert Watson-Watt". The Radar Pages. from the original on 17 December 2007. Retrieved 14 December 2007.
  18. ^ "Passive Covert Radar – Watson-Watt's Daventry Experiment Revisited". IET. from the original on 13 May 2011. Retrieved 13 December 2008.
  19. ^ a b c d Corrigan, R. (25 September 2008). (PDF). Andrés Guadamuz/The University of Edinburgh, School of Law. Archived from the original (PDF) on 3 September 2011. Retrieved 16 August 2009. {{cite journal}}: Cite journal requires |journal= (help)
  20. ^ a b "Tribute plan for radar inventor". BBC. 1 November 2006. from the original on 8 April 2008. Retrieved 16 August 2009.
  21. ^ "under the Radar?". Prospect. p. 10. from the original on 5 October 2015. Retrieved 4 October 2015.
  22. ^ Taylor, A. J. P. (1992). English history, 1914–1945. Oxford; New York: Oxford University Press. p. 392.
  23. ^ London Gazette Issue 35586 published on 5 June 1942. Page 2
  24. ^ "Scotland's little-known WWII hero who helped beat the Luftwaffe with invention of radar set, to be immortalised in film". Daily Record. 16 February 2017. from the original on 17 February 2017.
  25. ^ Administrator. "Microwaves101 – A Rough Justice". microwaves101.com. from the original on 6 January 2009.
  26. ^ Shafe, Michael (1982). University Education in Dundee 1881–1981: A Pictorial History. Dundee: University of Dundee. p. 106.
  27. ^ "Scottish Engineering Hall of Fame". engineeringhalloffame.org. from the original on 7 October 2013.
  28. ^ "Scottish engineering greats inducted into hall of fame". thecourier.co.uk. 5 October 2013. from the original on 7 October 2013.
  29. ^ "BBC News – Statue of radar pioneer Watson-Watt unveiled in Brechin". BBC News. 3 September 2014. from the original on 5 September 2014.
  30. ^ Jake Wallis Simons (5 September 2014). "Castles in the Sky, BBC Two, review: 'a bit worthy'". Telegraph.co.uk. from the original on 5 September 2014.
  31. ^ "Correspondence and papers of Sir Robert Alexander Watson-Watt". Scottish Archive Network Online Catalogue. Scottish Archive Network. from the original on 25 February 2018. Retrieved 15 December 2015.
  32. ^ "MS 228 Records relating to Sir Robert Alexander Watson-Watt". Archive Services Online Catalogue. University of Dundee. Retrieved 15 December 2015.
  33. ^ "How a trove of letters reveal the secret (And very tangled) life of the Scot who downed the Luftwaffe".
  34. ^ Entry number 115 in the marriage register of St Saviour's church, Hammersmith
  35. ^ "Sir Robert Watson Watt – Brechin's unsung war hero" Angus Heritage 4 December 2013 at the Wayback Machine
  36. ^ "Father of radar fought the menace from the sky" The Scotsman 20 August 2005

Sources

  • Brown, Louis (1999). Technical and Military Imperatives: A Radar History of World War 2. CRC Press. ISBN 978-1-4200-5066-0.
  • Lem, Elizabeth, The Ditton Park Archive
  • Celinscak, Mark. "Robert Watson-Watt" in Philosophers of War: The Evolution of History's Greatest Military Thinkers. Santa Barbara: ABC-CLIO. p. 489.
  • Sir Robert Watson-Watt bio
  • The Royal Air Force Air Defence Radar Museum at RRH Neatishead, Norfolk
  • The Watson-Watt Society of Brechin, Angus, Scotland

External links

  • Deflating British Radar Myths of World War II A comparison of contemporary British and German radar inventions and their use
  • Radar Development In England
  • Sir Robert Alexander Watson-Watt's biography
  • The Robert Watson-Watt Society

January 07, 2023
robert, watson, watt, robert, alexander, watson, watt, fraes, april, 1892, december, 1973, scottish, pioneer, radio, direction, finding, radar, technology, sirkcb, fraesbornrobert, alexander, watson, 1892, april, 1892brechin, angus, scotlanddied5, december, 19. Sir Robert Alexander Watson Watt KCB FRS FRAeS 13 April 1892 5 December 1973 was a Scottish pioneer of radio direction finding and radar technology 2 SirRobert Watson WattKCB FRS FRAeSBornRobert Alexander Watson 1892 04 13 13 April 1892Brechin Angus ScotlandDied5 December 1973 1973 12 05 aged 81 Inverness ScotlandKnown forRadarAwardsHughes Medal 1948 Elliott Cresson Medal 1957 Fellow of the Royal Society 1 KCB FRAeS Medal for MeritWatt began his career in radio physics with a job at the Met Office where he began looking for accurate ways to track thunderstorms using the radio signals given off by lightning This led to the 1920s development of a system later known as high frequency direction finding HFDF or huff duff Although well publicized at the time the system s enormous military potential was not developed until the late 1930s Huff duff allowed operators to determine the location of an enemy radio in seconds and it became a major part of the network of systems that helped defeat the threat of German U boats during World War II It is estimated that huff duff was used in about a quarter of all attacks on U boats In 1935 Watt was asked to comment on reports of a German death ray based on radio Watt and his assistant Arnold Frederic Wilkins quickly determined it was not possible but Wilkins suggested using radio signals to locate aircraft at long distances This led to a February 1935 demonstration where signals from a BBC short wave transmitter were bounced off a Handley Page Heyford aircraft 2 3 Watt led the development of a practical version of this device which entered service in 1938 under the code name Chain Home This system provided the vital advance information that helped the Royal Air Force win the Battle of Britain 1 4 After the success of his invention Watson Watt was sent to the US in 1941 to advise on air defence after Japan s attack on Pearl Harbor He returned and continued to lead radar development for the War Office and Ministry of Supply He was elected a Fellow of the Royal Society in 1941 was given a knighthood in 1942 and was awarded the US Medal for Merit in 1946 Contents 1 Early years 2 Early experiments 3 RADAR 3 1 The air defence problem 3 2 Aircraft detection and location 4 Civil Service trade union activities 5 Contribution to Second World War 6 Honours 7 Legacy 8 Business and financial life 9 Family life 10 See also 11 Notes 12 References 13 Sources 14 External linksEarly years EditWatson Watt a 5 was born in Brechin Angus Scotland on 13 April 1892 He claimed to be a descendant of James Watt the famous engineer and inventor of the practical steam engine but no evidence of any family relationship has been found 6 After attending Damacre Primary School and Brechin High School 7 he was accepted to University College Dundee then part of the University of St Andrews and which became Queen s College Dundee in 1954 and then the University of Dundee in 1967 Watson Watt had a successful time as a student winning the Carnelley Prize for Chemistry and a class medal for Ordinary Natural Philosophy in 1910 8 He graduated with a BSc in engineering in 1912 and was offered an assistantship by Professor William Peddie 9 the holder of the Chair of Physics at University College Dundee from 1907 to 1942 It was Peddie who encouraged Watson Watt to study radio or wireless telegraphy as it was then known and who took him through what was effectively a postgraduate class on the physics of radio frequency oscillators and wave propagation At the start of the Great War Watson Watt was working as an assistant in the college s Engineering Department 10 Early experiments EditIn 1916 Watson Watt wanted a job with the War Office but nothing obvious was available in communications Instead he joined the Meteorological Office which was interested in his ideas on the use of radio for the detection of thunderstorms Lightning gives off a radio signal as it ionizes the air and his goal was to detect this signal to warn pilots of approaching thunderstorms The signal occurs across a wide range of frequencies and could be easily detected and amplified by naval longwave sets In fact lightning was a major problem for communications at these common wavelengths 11 His early experiments were successful in detecting the signal and he quickly proved to be able to do so at ranges up to 2 500 km Location was determined by rotating a loop antenna to maximise or minimise the signal thus pointing to the storm The strikes were so fleeting that it was very difficult to turn the antenna in time to positively locate one Instead the operator would listen to many strikes and develop a rough average location 11 At first he worked at the Wireless Station of Air Ministry Meteorological Office in Aldershot Hampshire In 1924 when the War Department gave notice that they wished to reclaim their Aldershot site he moved to Ditton Park near Slough Berkshire The National Physical Laboratory NPL was already using this site and had two main devices that would prove pivotal to his work 11 The first was an Adcock antenna an arrangement of four masts that allowed the direction of a signal to be detected through phase differences Using pairs of these antennas positioned at right angles one could make a simultaneous measurement of the lightning s direction on two axes Displaying the fleeting signals was a problem This was solved by the second device the WE 224 oscilloscope recently acquired from Bell Labs By feeding the signals from the two antennae into the X and Y channels of the oscilloscope a single strike caused the appearance of a line on the display indicating the direction of the strike The scope s relatively slow phosphor only allowed the signal to be read long after the strike had occurred 12 Watt s new system was being used in 1926 and was the topic of an extensive paper by Watson Watt and Herd 13 The Met and NPL radio teams were amalgamated in 1927 to form the Radio Research Station with Watson Watt as director Continuing research throughout the teams had become interested in the causes of static radio signals and found that much could be explained by distant signals located over the horizon being reflected off the upper atmosphere This was the first direct indication of the reality of the Heaviside layer proposed earlier but at this time largely dismissed by engineers To determine the altitude of the layer Watt Appleton and others developed the squegger to develop a time base display which would cause the oscilloscope s dot to move smoothly across the display at very high speed By timing the squegger so that the dot arrived at the far end of the display at the same time as expected signals reflected off the Heaviside layer the altitude of the layer could be determined This time base circuit was key to the development of radar 14 After a further reorganization in 1933 Watt became Superintendent of the Radio Department of NPL in Teddington citation needed RADAR EditThe air defence problem Edit During the First World War the Germans had used Zeppelins as long range bombers over Britain and defences had struggled to counter the threat Since that time aircraft capabilities had improved considerably and the prospect of widespread aerial bombardment of civilian areas was causing the government anxiety Heavy bombers were now able to approach at altitudes that anti aircraft guns of the day were unable to reach 15 With enemy airfields across the English Channel potentially only 20 minutes flying time away bombers would have dropped their bombs and be returning to base before any intercepting fighters could get to altitude The only answer seemed to be to have standing patrols of fighters in the air but with the limited cruising time of a fighter this would require a huge air force An alternative solution was urgently needed and in 1934 the Air Ministry set up a committee the CSSAD Committee for the Scientific Survey of Air Defence chaired by Sir Henry Tizard to find ways to improve air defence in the UK citation needed Rumours that Nazi Germany had developed a death ray that was capable of destroying towns cities and people using radio waves were given attention in January 1935 by Harry Wimperis Director of Scientific Research at the Air Ministry He asked Watson Watt about the possibility of building their version of a death ray specifically to be used against aircraft 3 Watson Watt quickly returned a calculation carried out by his young colleague Arnold Wilkins showing that such a device was impossible to construct and fears of a Nazi version soon vanished He also mentioned in the same report a suggestion that was originally made to him by Wilkins who had recently heard of aircraft disturbing shortwave communications that radio waves might be capable of detecting aircraft Meanwhile attention is being turned to the still difficult but less unpromising problem of radio detection and numerical considerations on the method of detection by reflected radio waves will be submitted when required Wilkins s idea checked by Watt was promptly presented by Tizard to the CSSAD on 28 January 1935 16 Aircraft detection and location Edit Memorial at the Daventry site of the first successful RADAR experiments 52 11 46 N 1 03 00 W 52 195982 N 1 050121 W 52 195982 1 050121 Closeup of memorial plaque The first workable radar unit constructed by Robert Watson Watt and his team On 12 February 1935 Watson Watt sent the secret memo of the proposed system to the Air Ministry Detection and location of aircraft by radio methods Although not as exciting as a death ray the concept clearly had potential but the Air Ministry before giving funding asked for a demonstration proving that radio waves could be reflected by an aircraft 17 This was ready by 26 February and consisted of two receiving antennae located about 6 miles 9 7 km away from one of the BBC s shortwave broadcast stations at Daventry The two antennae were phased such that signals travelling directly from the station cancelled themselves out but signals arriving from other angles were admitted thereby deflecting the trace on a CRT indicator passive radar 18 Such was the secrecy of this test that only three people witnessed it Watson Watt his colleague Arnold Wilkins and a single member of the committee A P Rowe The demonstration was a success on several occasions the receiver showed a clear return signal from a Handley Page Heyford bomber flown around the site Prime Minister Stanley Baldwin was kept quietly informed of radar progress On 2 April 1935 Watson Watt received a patent on a radio device for detecting and locating an aircraft 3 In mid May 1935 Wilkins left the Radio Research Station with a small party including Edward George Bowen to start further research at Orford Ness an isolated peninsula on the Suffolk coast of the North Sea By June they were detecting aircraft at a distance of 16 mi 26 km which was enough for scientists and engineers to stop all work on competing sound based detection systems By the end of the year the range was up to 60 mi 97 km at which point plans were made in December to set up five stations covering the approaches to London citation needed One of these stations was to be located on the coast near Orford Ness and Bawdsey Manor was selected to become the main centre for all radar research To put a radar defence in place as quickly as possible Watson Watt and his team created devices using existing components rather than creating new components for the project and the team did not take additional time to refine and improve the devices So long as the prototype radars were in workable condition they were put into production 19 They conducted full scale tests of a fixed radar radio tower system attempting to detect an incoming bomber by radio signals for interception by a fighter 19 20 The tests were a complete failure with the fighter only seeing the bomber after it had passed its target The problem was not the radar but the flow of information from trackers from the Observer Corps to the fighters which took many steps and was very slow Henry Tizard Patrick Blackett and Hugh Dowding immediately set to work on this problem designing a command and control air defence reporting system with several layers of reporting that were eventually sent to a single large room for mapping Observers watching the maps would then tell the fighters what to do via direct communications 19 Radar coverage along the UK coast 1939 1940 By 1937 the first three stations were ready and the associated system was put to the test The results were encouraging and the government immediately commissioned construction of 17 additional stations This became Chain Home the array of fixed radar towers on the east and south coasts of England 19 20 By the start of World War II 19 were ready for the Battle of Britain and by the end of the war over 50 had been built The Germans were aware of the construction of Chain Home but were not sure of its purpose They tested their theories with a flight of the Zeppelin LZ 130 but concluded the stations were a new long range naval communications system citation needed As early as 1936 it was realized that the Luftwaffe would turn to night bombing if the day campaign did not go well Watson Watt had put another of the staff from the Radio Research Station Edward Bowen in charge of developing a radar that could be carried by a fighter Night time visual detection of a bomber was good to about 300 m and the existing Chain Home systems simply did not have the accuracy needed to get the fighters that close Bowen decided that an airborne radar should not exceed 90 kg 200 lb in weight or 8 ft 230 L in volume and should require no more than 500 watts of power To reduce the drag of the antennae the operating wavelength could not be much greater than one metre difficult for the day s electronics However Airborne Interception AI was perfected by 1940 and was instrumental in eventually ending The Blitz of 1941 Watson Watt justified his choice of a non optimal frequency for his radar with his oft quoted cult of the imperfect which he stated as Give them the third best to go on with the second best comes too late and the best never comes citation needed Civil Service trade union activities EditBetween 1934 and 1936 Watson Watt was president of the Institution of Professional Civil Servants now a part of Prospect the union for professionals The union speculates that at this time he was involved in campaigning for an improvement in pay for Air Ministry staff 21 Contribution to Second World War Edit Sir Robert Alexander Watson Watt ca 1944 In his English History 1914 1945 the historian A J P Taylor paid the highest of praise to Watson Watt Sir Henry Tizard and their associates who developed radar crediting them with being fundamental to victory in the Second World War 22 In July 1938 Watson Watt left Bawdsey Manor and took up the post of Director of Communications Development DCD RAE In 1939 Sir George Lee took over the job of DCD and Watson Watt became Scientific Advisor on Telecommunications SAT to the Ministry of Aircraft Production travelling to the US in 1941 to advise them on the severe inadequacies of their air defence illustrated by the Pearl Harbor attack He was knighted by George VI in 1942 and received the US Medal for Merit in 1946 23 24 Sir Robert descends from a plinth in Trafalgar Square London in 1961 after speaking at a rally protesting at the spread of nuclear weapons Ten years after his knighthood Watson Watt was awarded 50 000 by the UK government for his contributions in the development of radar He established a practice as a consulting engineer In the 1950s he moved to Canada and later he lived in the US where he published Three Steps to Victory in 1958 Around 1958 he appeared as a mystery challenger on the American television programme To Tell The Truth In 1956 Watson Watt reportedly was pulled over for speeding in Canada by a radar gun toting policeman His remark was Had I known what you were going to do with it I would never have invented it 2 He wrote an ironic poem A Rough Justice afterwards Pity Sir Robert Watson Watt strange target of this radar plot And thus with others I can mention the victim of his own invention His magical all seeing eye enabled cloud bound planes to fly but now by some ironic twist it spots the speeding motorist and bites no doubt with legal wit the hand that once created it 25 Honours EditIn 1945 Watson Watt was invited to deliver the Royal Institution Christmas Lecture on Wireless In 1949 a Watson Watt Chair of Electrical Engineering was established at University College Dundee 26 In 2013 he was one of four inductees to the Scottish Engineering Hall of Fame 27 28 Legacy Edit Memorial to Watson Watt at Brechin in Angus Scotland Memorial to the Birth of Radar at Stowe Nine Churches naming Watson Watt and Arnold Wilkins On 3 September 2014 a statue of Sir Robert Watson Watt was unveiled in Brechin by the Princess Royal 29 One day later the BBC Two drama Castles in the Sky aired with Eddie Izzard in the role of Watson Watt 30 A collection of some of the correspondence and papers of Watson Watt is held by the National Library of Scotland 31 A collection of papers relating to Watson Watt is also held by Archive Services at the University of Dundee 32 A briefing facility at RAF Boulmer has been named the Watson Watt auditorium in his honour citation needed Business and financial life EditWatson Watt had a problematic business and financial life 33 Family life EditWatson Watt was married 34 on 20 July 1916 in Hammersmith London to Margaret Robertson d 1988 the daughter of a draughtsman they later divorced and he remarried in 1952 in Canada 35 His second wife was Jean Wilkinson who died in 1964 36 He returned to Scotland in the 1960s 2 In 1966 at the age of 74 he proposed to Dame Katherine Trefusis Forbes who was 67 years old at the time and had also played a significant role in the Battle of Britain as the founding Air Commander of the Women s Auxiliary Air Force which supplied the radar room operatives They lived together in London in the winter and at The Observatory Trefusis Forbes summer home in Pitlochry Perthshire during the warmer months They remained together until her death in 1971 Watson Watt died in 1973 aged 81 in Inverness They are buried together in the churchyard of the Episcopal Church of the Holy Trinity at Pitlochry 2 See also EditHistory of radarNotes Edit the hyphenated name is used herein for consistency although he did not adopt it until 1942References Edit a b Ratcliffe J A 1975 Robert Alexander Watson Watt 13 April 1892 5 December 1973 Biographical Memoirs of Fellows of the Royal Society 21 548 568 doi 10 1098 rsbm 1975 0018 S2CID 72585933 a b c d e Making waves Robert Watson Watt the pioneer of radar BBC 16 February 2017 Archived from the original on 28 February 2017 a b c British Patent for Radar System for Air Defense Granted to Robert Watson Watt American Physical Society 17 February 2017 Archived from the original on 2 December 2016 Watson Watt Sir Robert The Pulse of Radar Dial Press 1959 London Gazette Issue 35618 published on 3 July 1942 Page 39 Nicoll Steve July 2017 Robert Alexander Watson Watt Britain at War 76 Sir Robert Watson Watt Dick Barrett Archived from the original on 5 March 2008 Retrieved 26 February 2008 100 years ago Archives Records and Artefacts at the University of Dundee Archived from the original on 4 March 2016 Retrieved 15 December 2015 Allen H S 1946 Prof William Peddie Nature 158 4002 50 51 Bibcode 1946Natur 158 50A doi 10 1038 158050b0 Shafe Michael 1982 University Education in Dundee 1881 1981 A Pictorial History Dundee University of Dundee pp 58 75 and 88 a b c Brown 1999 p 45 Brown 1999 p 46 R A Watt and J F Herd An instantaneous direct reading radiogoniometer Archived 2 February 2014 at the Wayback Machine Journal of the Institution of Electrical Engineers Volume 64 February 1926 pp 611 622 O S Puckle Time Bases Their Design and Development Chapman amp Hall 1943 Evans R J 18 September 2008 Hitler and the origins of the war 1919 1939 Lecture transcript Gresham College Archived from the original on 17 November 2010 Retrieved 16 August 2009 Buderi Robert 1996 The Invention That Changed the World How a Small Group of Radar Pioneers Won the Second World War and Launched a Technical Revolution 1998 ed Simon amp Schuster p 55 ISBN 978 0 684 83529 7 Robert Watson Watt The Radar Pages Archived from the original on 17 December 2007 Retrieved 14 December 2007 Passive Covert Radar Watson Watt s Daventry Experiment Revisited IET Archived from the original on 13 May 2011 Retrieved 13 December 2008 a b c d Corrigan R 25 September 2008 Airborne minefields and Fighter Command s information system PDF Andres Guadamuz The University of Edinburgh School of Law Archived from the original PDF on 3 September 2011 Retrieved 16 August 2009 a href Template Cite journal html title Template Cite journal cite journal a Cite journal requires journal help a b Tribute plan for radar inventor BBC 1 November 2006 Archived from the original on 8 April 2008 Retrieved 16 August 2009 under the Radar Prospect p 10 Archived from the original on 5 October 2015 Retrieved 4 October 2015 Taylor A J P 1992 English history 1914 1945 Oxford New York Oxford University Press p 392 London Gazette Issue 35586 published on 5 June 1942 Page 2 Scotland s little known WWII hero who helped beat the Luftwaffe with invention of radar set to be immortalised in film Daily Record 16 February 2017 Archived from the original on 17 February 2017 Administrator Microwaves101 A Rough Justice microwaves101 com Archived from the original on 6 January 2009 Shafe Michael 1982 University Education in Dundee 1881 1981 A Pictorial History Dundee University of Dundee p 106 Scottish Engineering Hall of Fame engineeringhalloffame org Archived from the original on 7 October 2013 Scottish engineering greats inducted into hall of fame thecourier co uk 5 October 2013 Archived from the original on 7 October 2013 BBC News Statue of radar pioneer Watson Watt unveiled in Brechin BBC News 3 September 2014 Archived from the original on 5 September 2014 Jake Wallis Simons 5 September 2014 Castles in the Sky BBC Two review a bit worthy Telegraph co uk Archived from the original on 5 September 2014 Correspondence and papers of Sir Robert Alexander Watson Watt Scottish Archive Network Online Catalogue Scottish Archive Network Archived from the original on 25 February 2018 Retrieved 15 December 2015 MS 228 Records relating to Sir Robert Alexander Watson Watt Archive Services Online Catalogue University of Dundee Retrieved 15 December 2015 How a trove of letters reveal the secret And very tangled life of the Scot who downed the Luftwaffe Entry number 115 in the marriage register of St Saviour s church Hammersmith Sir Robert Watson Watt Brechin s unsung war hero Angus Heritage Archived 4 December 2013 at the Wayback Machine Father of radar fought the menace from the sky The Scotsman 20 August 2005Sources EditBrown Louis 1999 Technical and Military Imperatives A Radar History of World War 2 CRC Press ISBN 978 1 4200 5066 0 Lem Elizabeth The Ditton Park Archive Celinscak Mark Robert Watson Watt in Philosophers of War The Evolution of History s Greatest Military Thinkers Santa Barbara ABC CLIO p 489 Sir Robert Watson Watt bio The Royal Air Force Air Defence Radar Museum at RRH Neatishead Norfolk The Watson Watt Society of Brechin Angus ScotlandExternal links EditDeflating British Radar Myths of World War II A comparison of contemporary British and German radar inventions and their use Radar Development In England Sir Robert Alexander Watson Watt s biography The Robert Watson Watt Society Retrieved from https en wikipedia org w index php title Robert Watson Watt amp oldid 1124625083, wikipedia, wiki, book, books, library,

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