VERLORT Radar
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[[Image:muc-verlort.jpg|right|thumbnail|190px|The VERLORT radar at Muchea:<BR>''Photo - ???'']] | [[Image:muc-verlort.jpg|right|thumbnail|190px|The VERLORT radar at Muchea:<BR>''Photo - ???'']] | ||
- | The '''VER'''y '''LO'''ng '''R'''ange '''T'''racking (VERLORT) radar was an extended-range version of the '''SCR-584''', and was often credited as "the radar that won WW II". The range was increased from 650 Km to 4000 Km and the dish diameter from 1.8 m to 3 m to give the radar space tracking capabilities. The Red Lake (Woomera) Mercury tracking station used the more accurate AN/FPS-16 radar installed at Woomera for previous space activities. | + | The '''VER'''y '''LO'''ng '''R'''ange '''T'''racking (VERLORT) radar was an extended-range version of the '''SCR-584''', and was often credited as "the radar that won WW II". The Verlort range was increased from 650 Km to 4000 Km and the dish diameter from 1.8 m to 3 m to give the radar space-tracking capabilities. The Red Lake (Woomera) Mercury tracking station used the more accurate AN/FPS-16 radar installed at Woomera for previous space activities. |
[[Image:cro-verlort.jpg|left|thumbnail|180px|The VERLORT radar reinstalled at Carnarvon just beside the AcqAid antennas:<BR>''Photo - Alan Gilham'']] | [[Image:cro-verlort.jpg|left|thumbnail|180px|The VERLORT radar reinstalled at Carnarvon just beside the AcqAid antennas:<BR>''Photo - Alan Gilham'']] | ||
- | The VERLORT radar performed reliably for the six Mercury orbital missions. It was then relocated to the new Gemini tracking station at Carnarvon as an acquisition aid and back-up for the even more accurate FPQ-6 radar installed there. Although the VERLORT was kept operational for the first few Carnarvon missions it was soon not required because the FPQ-6 was very reliable and other acquisition methods proved sufficient. | + | The Verlort radar performed reliably for the six Mercury orbital missions. It was then relocated to the new Gemini tracking station at Carnarvon as an acquisition aid and back-up for the even more accurate FPQ-6 radar installed there. Although the Verlort was kept operational for the first few Carnarvon missions it was soon not required because the FPQ-6 was very reliable and other acquisition methods proved sufficient. |
==Some technical descriptions== | ==Some technical descriptions== | ||
[[Image:Helical scan.jpg|right|thumbnail|150px|Helical scan mechanism: ''Image – ‘Electronics’; Fig 2, Dec ’45, p.104'']] | [[Image:Helical scan.jpg|right|thumbnail|150px|Helical scan mechanism: ''Image – ‘Electronics’; Fig 2, Dec ’45, p.104'']] | ||
- | The SCR family of radars, developed at the MIT laboratories, was remarkable for the innovative MIT solutions to radar operations now met in modern radars using electronic methods. | + | The SCR family of radars, developed at the MIT laboratories, was remarkable for the innovative MIT solutions to radar operations that are now met in modern radars by electronic methods. |
- | The Verlort Plan Position Indicator (PPI) was driven by a mechanical computer once target acquisition occurred with the radar operator needing to keep a ‘hairline’ indicator manually centred on the target’s echo to maintain track. | + | The Verlort Plan Position Indicator (PPI) was driven by a mechanical computer once target acquisition occurred; the radar operator needed to keep a ‘hairline’ indicator manually centred on the target’s echo to maintain track. |
Even more intriguing were the target acquisition techniques. | Even more intriguing were the target acquisition techniques. | ||
- | For targets where only crude position information was available, a helical scan was used to acquire. The dish was swung in a circle at 6 rpm along the expected path with the reflector tilted to and fro about 4 deg per dish revolution to create a helical spiral about 20 deg wide along the expected track path - see 'Helical scan mechanism' diagram on right. | + | For targets where only crude position information was available, a helical scan was used to acquire the target. The dish was swung in a circle at 6 rpm along the expected path with the reflector tilted to and fro about 4° per dish revolution to create a helical spiral about 20° wide along the expected track path - see 'Helical scan mechanism' diagram on right. |
- | Where there was more certainty about the target path, a nutating scan mode was used where the slightly offset dipole feed was rotated rapidly to produce off-axis radiation to increase the effective beam width from 2.5 deg to about 5.5 deg. The nutation was switched off when the target was acquired. See ‘conical scan beam’ diagram below left and ‘nutating antenna dipole feed’ below right. | + | Where there was more certainty about the target path, a nutating scan mode was used where the slightly offset dipole feed was rotated rapidly to produce off-axis radiation to increase the effective beam width from 2.5° to about 5.5° . The nutation was switched off when the target was acquired. See ‘conical scan beam’ diagram below left and ‘nutating antenna dipole feed’ below right. |
[[Image:Conical beam.jpg|left|thumbnail|250px|A conical scan beam:<BR> ''Image – ‘Electronics’; Fig 1, Nov ’45, p.104'']] | [[Image:Conical beam.jpg|left|thumbnail|250px|A conical scan beam:<BR> ''Image – ‘Electronics’; Fig 1, Nov ’45, p.104'']] |
Revision as of 07:44, 8 May 2007
The VERy LOng Range Tracking (VERLORT) radar was an extended-range version of the SCR-584, and was often credited as "the radar that won WW II". The Verlort range was increased from 650 Km to 4000 Km and the dish diameter from 1.8 m to 3 m to give the radar space-tracking capabilities. The Red Lake (Woomera) Mercury tracking station used the more accurate AN/FPS-16 radar installed at Woomera for previous space activities.
The Verlort radar performed reliably for the six Mercury orbital missions. It was then relocated to the new Gemini tracking station at Carnarvon as an acquisition aid and back-up for the even more accurate FPQ-6 radar installed there. Although the Verlort was kept operational for the first few Carnarvon missions it was soon not required because the FPQ-6 was very reliable and other acquisition methods proved sufficient.
Some technical descriptions
The SCR family of radars, developed at the MIT laboratories, was remarkable for the innovative MIT solutions to radar operations that are now met in modern radars by electronic methods.
The Verlort Plan Position Indicator (PPI) was driven by a mechanical computer once target acquisition occurred; the radar operator needed to keep a ‘hairline’ indicator manually centred on the target’s echo to maintain track.
Even more intriguing were the target acquisition techniques.
For targets where only crude position information was available, a helical scan was used to acquire the target. The dish was swung in a circle at 6 rpm along the expected path with the reflector tilted to and fro about 4° per dish revolution to create a helical spiral about 20° wide along the expected track path - see 'Helical scan mechanism' diagram on right.
Where there was more certainty about the target path, a nutating scan mode was used where the slightly offset dipole feed was rotated rapidly to produce off-axis radiation to increase the effective beam width from 2.5° to about 5.5° . The nutation was switched off when the target was acquired. See ‘conical scan beam’ diagram below left and ‘nutating antenna dipole feed’ below right.
For a detailed technical description of the SCR-584 radar published in the November & December 1945 issues of ‘Electronics’ magazine refer to http://www.hamhud.net/darts/scr584.html.