FPQ-6 Radar
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| - | The '''AN-FPQ-6 Military Precision Instrumentation Radar (MIPIR)''' was the most precise radar in the world during the time it operated at Carnarvon. It was the only one in the Southern Hemisphere; consequently, it was called onto support almost everything that was launched from the USA. Carnarvon FPQ-6 tracked virtually every day, accumulating such a huge number of diverse objects it is a pity that no record was kept of its support. | + | The '''AN-FPQ-6 Military Precision Instrumentation Radar (MIPIR)''' was the most precise radar in the world during the time it operated at Carnarvon. It was the only one in the Southern Hemisphere; consequently, it was called onto support almost everything that was launched from the USA. |
| - | FPQ-6 supported the launch orbit of every satellite and spacecraft launched by any agency from the USA into a non-polar orbit. All passed within range of Carnarvon midway through the critical first orbit enabling the Carnarvon FPQ-6 to give the first sure indication that a good orbit would be achieved. Carnarvon gave prime support for all Manned Space Flight Network (MSFN) missions; for all Deep Space Network (DSN) missions through early orbit and transition and into a trans-lunar or trans-planetary path; and for various communications satellites throughout their launch orbit and transition into geosynchronous orbit within the Indian and Pacific regions. | + | Carnarvon FPQ-6 tracked virtually every day, accumulating such a huge number of diverse objects it is a pity that no record was kept of its support. It supported the launch orbit of every satellite and spacecraft launched by any agency from the USA into a non-polar orbit. All passed within range of Carnarvon midway through the critical first orbit enabling the Carnarvon FPQ-6 to give the first sure indication that a good orbit would be achieved. Carnarvon gave prime support for all Manned Space Flight Network (MSFN) missions; for all Deep Space Network (DSN) missions through early orbit and transition and into a trans-lunar or trans-planetary path; and for various communications satellites throughout their launch orbit and transition into geosynchronous orbit within the Indian and Pacific regions. |
| It also provided tracking and orbit prediction support to a large number of US Department of Defense (DoD) Orbiting Vehicle (OV) satellites - usually individually by negotiation between the US and Australian governments to ensure the non-military status of NASA was being preserved. And it was known to skin-track some of the early Soviet spacecraft until it was instructed to desist for fear of alienating the USSR. | It also provided tracking and orbit prediction support to a large number of US Department of Defense (DoD) Orbiting Vehicle (OV) satellites - usually individually by negotiation between the US and Australian governments to ensure the non-military status of NASA was being preserved. And it was known to skin-track some of the early Soviet spacecraft until it was instructed to desist for fear of alienating the USSR. | ||
Revision as of 02:58, 18 February 2007
FPQ-6 Radar
- Antenna structure
- Tracking and Ranging
- Brief system details
- RCA Computer
- Key Q6 Mission Activity
- Research activity
- BDA, CRO & RCA: Q6 partners
- Other Q-6 tales
Back to Station Equipment
Sections not yet complete are 'Key Q-6 Mission Activity' and 'BDA, CRO and RCA: Q6 partners'
The AN-FPQ-6 Military Precision Instrumentation Radar (MIPIR) was the most precise radar in the world during the time it operated at Carnarvon. It was the only one in the Southern Hemisphere; consequently, it was called onto support almost everything that was launched from the USA.
Carnarvon FPQ-6 tracked virtually every day, accumulating such a huge number of diverse objects it is a pity that no record was kept of its support. It supported the launch orbit of every satellite and spacecraft launched by any agency from the USA into a non-polar orbit. All passed within range of Carnarvon midway through the critical first orbit enabling the Carnarvon FPQ-6 to give the first sure indication that a good orbit would be achieved. Carnarvon gave prime support for all Manned Space Flight Network (MSFN) missions; for all Deep Space Network (DSN) missions through early orbit and transition and into a trans-lunar or trans-planetary path; and for various communications satellites throughout their launch orbit and transition into geosynchronous orbit within the Indian and Pacific regions.
It also provided tracking and orbit prediction support to a large number of US Department of Defense (DoD) Orbiting Vehicle (OV) satellites - usually individually by negotiation between the US and Australian governments to ensure the non-military status of NASA was being preserved. And it was known to skin-track some of the early Soviet spacecraft until it was instructed to desist for fear of alienating the USSR.
Any support FPQ-6 provided was secondary to its requirement to track all manned space flight passes over Carnarvon. But support for other satellites was not confined to early orbit definition and any critical transition phase. Beyond then it would regularly track satellites to redefine their orbital parameters. Ultimately it was involved in tracking them during their final orbits as they decayed to a fiery death on re-entry into the Earth’s atmosphere.
Unique to the FPQ-6 was the way its computer was an integral part of the system. It could provide critical orbital parameters directly to the next radar along an orbital path so that it in turn could acquire and track independent of central network computer support.
An interesting aspect of the FPQ-6 radar teams around the tracking network, particularly Bermuda (BDA) and Carnarvon (CRO), was the way they interacted with each other. They became a close-knit group within a NASA team of many thousands - almost a closed society - and were exemplars of how an operational team could interact with the designers and manufacturers to improve the performance of their equipment.
