 AN/FPS-35 atFortuna Air Force Station | |
| Country of origin |  United States |
|---|---|
| Manufacturer | Sperry Corp[1] |
| Introduced | December 1960; 64 years ago (1960-12) |
| No. built | 12 |
| Type | Early warning radar |
| Frequency | UHF, 420 to 450 MHz (0.71 to 0.67 m)[1] |
| PRF | 333 pps |
| RPM | 5 rpm |
| Range | 250 mi (220 nmi; 400 km) |
| Azimuth | 360° |
TheAN/FPS-35 was a long rangeearly warning radar used within theSAGE network and its successors. It was one of the largestair defense radars ever produced, with an antenna 126 feet (38 m) across supported on one of the largestrolling-element bearings in the world.[2]
The FPS-35 was one of a suite radars developed under a 1955Rome Air Development Center project to introduce designs that were more resistant tojamming through the use offrequency diversity. The -35 shifted frequency between 420 to 450 MHz (0.71 to 0.67 m), while the similarAN/FPS-24 operated between 214 and 236 MHz (1.40 and 1.27 m) and theAN/FPS-28 between 510 and 690 MHz (0.59 and 0.43 m). These radars also incorporatedmoving target indication (MTI) in order to deal with significant problems that earlier designs had withradar clutter, which the SAGE computers were not able to process.
The prototype was built atThomasville Air Force Station and declaredoperational in December 1960. The design proved to have many problems and only four were fully operational by 1962. A total of twelve were eventually installed. The unit atMontauk AFS produced strong interference withUHF television signals and was turned off in 1961 to be recalibrated, which had to happen several more times during its lifetime. Weighing more than 70 short tons (140,000 lb; 64,000 kg),[1] the size of the antennas caused serious maintenance problems, and in 1966 the unit atFortuna AFS collapsed onto the underlying building.
The last operational unit was at Montauk, decommissioned in 1981. In 2002 this site was added to theNational Register of Historic Places.[3]
The difficultly of manually arranging an interception of a jet powered bomber ledGeorge E. Valley Jr., formerly of theMIT Radiation Laboratoryradar development labs, to propose using a computer to handle as many of the tasks as possible. MIT was no longer willing to host a military organization on-campus, which led to the 1951 creation of theLincoln Laboratory to develop these concepts. In April, they demonstrated the transmission of radar information over telephone lines to the Whirlwind II computer, which successfully developed a "track". A follow-up "Summer Study Group" in 1952 saw no major barriers to deployment and recommended construction begin for a 1954 operational date.[4]
One issue raised during the Summer Study was the problem of low-flying aircraft. The detection abilities of a ground-based radar are focused into a region that looks like a wide, vertical cone centered on the radar, with the ability to see distant objects only at high altitudes due to theradar horizon. With a chart of known radar sites, an attacker could lower their altitude and fly between the stations. The group suggested adding airborne radar systems, whose cone-shaped detection pattern would be inverted, meaning it had its best detection at the longest ranges. This had the disadvantage that the carrier aircraft would often be flying in heavy cloud and rain, blocking its view. Lincoln Laboratory began developing a suitable system by lowering the operational frequency from themicrowave region, which scattered heavily on water (which is howmicrowave ovens work) into theUHF region which reduced this issue. Another issue is that the ground or water produces a massive return, but this could be filtered out using a technique known asmoving target indication (MTI).[5]
The follow-on to the early computer experiments was a single station known as the Cape Cod System. By 1954, this had demonstrated several serious problems when fed data from existing ground radars. One was that fixed objects like high hills produced permanent echos on the display. Transient events like strong rain and large flocks of birds produced similar images. It had been intended that these radars use MTI to eliminate fixed targets like these, but the MTI technique was difficult to implement on these microwave frequency radars, and many false targets were fed back to SAGE.[5]
Lincoln Labs responded by suggesting they build a ground-based version of their UHF airborne radar, by this time known asAN/APS-70, whose MTI system was known to work well.[6] Work on this new design, initially known as XD-1, began in the fall of 1954 on Jug Handle Hill in Maine. It was operational in October 1955. In order to match the 1.5° resolution of theAN/FPS-3, the antenna had to be 120 feet (37 m) wide, producing a massive installation that had to be supported on a complex steeltruss work tower system. This system was later upgraded with twoAN/FPS-6height finder radars and became an operational site under the new designationAN/FPS-31.[7]
With the conversion of the XD-1 to operational use, in 1959 Lincoln built a second example at Boston Hill outsideNorth Andover, Massachusetts. This example was known as CCM Radar Mark I, CCM referring to its use to developcounter-countermeasures.[8]
During this same period, the SAGE deployment was ramping up, mostly using the AN/FPS-3 as a primary radar and the AN/FPS-6 height finders. Both worked in narrow frequency bands, 1.3 GHz (23 cm) for the FPS-3, and 2.9 GHz (10 cm) for the AN/FPS-6.[8]
In November 1953, French companyCompagnie générale de la télégraphie sans fil (CSF) revealed theircarcinotron tube, able to generate a wide bandwidth of frequencies by changing the input voltage. Testing in theUK in early 1954 demonstrated that by broadcasting across the band of known radars, the even small signals from the carcinotron were strong enough to produce false returns that completely blanked out the radar display, effectivelyjamming or preventing its use. It appeared to render all long-range radars useless.[9]
It was not long before a number of solutions to this problem were identified, primarily by usingfrequency agility, the ability to shift the frequency within a certain band. Faced with a radar that can operate across such a selection of frequencies, the jammer is forced to send out signals on all of these, a concept known asbarrage jamming. In doing so they guarantee coverage of the frequency the radar is operating on, but at the same time the energy on the narrow frequency of the radar at any given instant is greatly reduced. Combining this with greatly increased transmission energy from the ground radars allows them to overwhelm the jammer's now diluted signal.[9]
To take advantage of this concept, in June 1955 theRome Air Development Center (RADC) began a program developing new radars operating across a wide band of frequencies fromVHF to microwave, also able to shift transmitted frequencies within the selected band. Four systems were outlined, theGeneral ElectricAN/FPS-24 that operated in the VHF range between 214 and 236 MHz (1.40 and 1.27 m), Sperry's AN/FPS-35 in the UHF range between 400 and 450 MHz (0.75 and 0.67 m), theRaytheonAN/FPS-28 also in the UHF band from 510 to 690 MHz (0.59 to 0.43 m), and theWestinghouse3-dimensional radarAN/FPS-27 in theS-band from 2,320 to 2,680 MHz (0.129 to 0.112 m).[10] By deploying these radars so they overlapped each other's frequencies, an attacker would have to carry a variety of carcinotron transmitters to effectively jam these widely separated bands. As the size of the carcinotron is a function of wavelength, ones for the lower VHF and UHF frequencies would be large, reducing the aircraft's payload for weapons.[11]
The FPS-35's basic design parameters were based on the FPS-31, but ended up being a very different product. Among the more obvious changes were a newparabolic reflector design, and a new massive bearing system to rotate it. RADC placed a contract for four prototype units to be installed at existing Air Force bases.[8]
Sperry built 12 of the long range radars, detecting objects 200 miles (320 km) away, in the 1960s. They were to succeed existingSemi Automatic Ground Environment (SAGE) radars providing enhancedelectronic countermeasures (ECM). Operating from 420 to 450 MHz (0.71 to 0.67 m) resulted in using antennas that weighed between 70 and 80 short tons (64 and 73 t), exhibiting numerous problems.[1] The concrete tower bases were 84 feet 6 inches (25.76 m) high, with 5 floors, measuring 60 feet 3 inches (18.36 m) square in side dimensions.
The prototype was developed at the Thomasville Aircraft Control and Warning Station inThomasville, Alabama.[12]
The 85-foot (26 m) enclosed radar towers supporting all 12 of the FPS-35 antennas were prominentlandmarks. All were of the same basic design with ten constructed primarily from concrete and two based on a steel frame structure (sites Baker and Finley). Only the radar tower at Baker has been demolished.[12]
The 23 radar towers used by theAN/FPS-24 and the AN/FPS-35 radar sets were of similar designs (concrete or steel frame) and were designed under direction of RADC. The radar tower at Thomasville has an RADC plaque next to one from Sperry Corporation. Only the FPS-35 tower at Baker included aradome protecting the antenna. This radome was attached to a separate steel tower called a Radome Support Structure (RSS) surrounding the radar tower to its full height.[12] With the antenna, the structure's total height was 150 feet (46 m).
AN/FPS-35 Radar Tower and Antenna | |
 AN/FPS-35 radar atCamp Hero State Park,Montauk, New York. The radar rises well above its surrounding trees. | |
  | |
| Location | Camp Hero State Park |
|---|---|
| Nearest city | Montauk, New York |
| Coordinates | 41°3′44.81″N71°52′28.24″W / 41.0624472°N 71.8745111°W /41.0624472; -71.8745111 |
| Built | 1960; 65 years ago (1960) |
| NRHP reference No. | 02000615 |
| Significant dates | |
| Added to NRHP | June 4, 2002[3] |
| Designated NHS | June 4, 2002 |
All of the FPS-35 radars have been dismantled except for the one atCamp Hero State Park on the eastern tip ofLong Island inMontauk, New York. It was the last to operate, shutting down in January 1981, and the radar tower is the only one still with an antenna on the roof. The tower also contains some of the radar set equipment and cabinets. The antenna was repaired with parts from the Sault Ste. Marie station after it closed in October 1979. The Montauk antenna is very corroded and can not be rotated.[12]
The structure was listed on theNational Register of Historic Places in 2002.[3][13] Fishermen on theAtlantic Ocean andBlock Island Sound lobbied to save it since the massiveradar tower was a better daytime landmark than theMontauk Point Lighthouse.[14]
The 150-foot (46 m) tower dominates the environs able to be seen from as far away asCharlestown, Rhode Island, 22 miles (35 km) to the east andOrient Point, New York 20 miles (32 km) to the west.
The Montauk radar has worked its way into anconspiracy theory that it was used in time travel experiments called theMontauk Project.
