Ballistic Missile Early Warning System

Template:Short description Template:Use dmy datesTemplate:Use American English Template:For Template:Infobox military installation

The RCA 474L Ballistic Missile Early Warning System (BMEWS, 474L System,Template:R Project 474L) was a United States Air Force Cold War early warning radar, computer, and communications system,<ref>Template:Cite book</ref> for ballistic missile detection. The network of twelve radars,<ref name=StoneBanner /> which was constructed beginning in 1958 and became operational in 1961, was built to detect a mass ballistic missile attack launched on northern approaches [for] 15 to 25 minutes' warning time<ref>Template:Cite report</ref> also provided Project Space Track<ref>{{#invoke:citation/CS1|citation |CitationClass=web }}</ref> satellite data (e.g., about one-quarter of SPADATS observations).<ref>Template:Cite book</ref>

It was replaced by the Solid State Phased Array Radar System in 2001.<ref name=Chapman>Template:Cite book</ref>

BackgroundEdit

The Ballistic Missile Early Warning System (BMEWS) was a radar system built by the United States (with the cooperation of Canada and Denmark on whose territory some of the radars were sited) during the Cold War to give early warning of a Soviet intercontinental ballistic missile (ICBM) nuclear strike, to allow time for US bombers to get off the ground and land-based US ICBMs to be launched, to reduce the chances that a preemptive strike could destroy US strategic nuclear forces.

The shortest (great circle) route for a Soviet ICBM attack on North America is across the North Pole, so the BMEWS facilities were built in the Arctic at Clear Space Force Station in central Alaska, and Site J near Pituffik Space Base, North Star Bay, Greenland. When it became clear in the 1950s that the Soviet Union was developing ICBMs, the US was already building an early-warning radar system in the Arctic, the DEW line, but it was designed to detect bombers and did not have the capability of tracking ICBMs.

The challenges of designing a system that could detect and track a massive strike of hundreds of ICBMs were formidable. The radar sites were located as far north in the Arctic as possible, to give maximum warning time of an attack. However, the time between when a Soviet missile would rise above the horizon and be detected and when it would reach its target in the US was only 10 to 25 minutes.

EquipmentEdit

BMEWS consisted of two types of radars and various computer and reporting systems to support them. The first type of radar consisted of very large, fixed rectangular partial-parabolic reflectors with two primary feed points. They produced two fan-shaped microwave beams that allowed them to detect targets across a very wide horizontal front at two narrow vertical angles. These were used to provide wide-front coverage of missiles rising into their radar horizon, and by tracking them at two points as they climbed, enough information to determine their rough trajectory.

The second type of radar was used for fine tracking of selected targets, and consisted of a very large steerable parabolic reflector under a large radome. These radars provided high-resolution angular and ranging information that was fed to a computer for rapid calculation of the probable impact points of the missile warheads. The systems were upgraded several times over their lifetime, replacing the mechanically scanned systems with phased array radar that could perform both roles at the same time.

BMEWS equipment included:<ref name=DoD1960>Template:Cite report</ref>

• General Electric AN/FPS-50 Radar Set, a UHF (440 MHz) detector with transmitter having an organ-pipe scanner feed, fixed 1,500 ton<ref>Template:Cite news</ref> parabolic-torus reflector, and receiver with Doppler filter bank to scan with two horizontally-sweeping fans<ref name=StoneBanner /> for as many as ~12,000 observations per day<ref name=BMW /> for surveillance (determining range, position, and range rate) of space objects<ref>{{#invoke:citation/CS1|citation

|CitationClass=web }}</ref>

• RCA AN/FPS-49 Radar Set, a five-horn monopulse tracker (e.g., three at Site III) and FPS-49A variant (different radome) at Thule<ref>{{#invoke:citation/CS1|citation

|CitationClass=web }}</ref> (vacuum tubes 10 feet tall in transmitter buildings are used to warm the site)<ref>Template:Cite newsTemplate:Dead link</ref>

• RCA AN/FPS-92 Radar Set, an upgraded FPS-49 featuring more elaborate receiver circuits and hydrostatic bearings<ref name=BMW /> at Clear<ref>{{#invoke:citation/CS1|citation

|CitationClass=web }}</ref>

• Sylvania AN/FSQ-53 Radar Monitoring Set, with console and Signal Data Converter Group<ref>{{#invoke:citation/CS1|citation

|CitationClass=web }}</ref> ("data take-off unit")Template:Citation needed

• Sylvania AN/FSQ-28 Missile Impact Predictor Set, with duplex IBM-7090 TX solid-state computers e.g., in Building 2 at Thule <ref>{{#invoke:citation/CS1|citation

|CitationClass=web }}</ref>Template:Unreliable source? and part of the AN/FPA-21 Radar Central Computer at Site III<ref>Template:Cite report</ref>—Satellite Information Processor (SIP) software was later added at Site III for use on the backup IBM 7090.<ref>{{#invoke:citation/CS1|citation |CitationClass=web }} the USA and UK agreed to be separately responsible for their own rearward data handling systems.’ [46] The UK systems were to meet Air Staff Requirement 2208 and called for ‘display of processed IRBM data at the Air Defence Operations Centre (ADOC), the Bomber Command Operations Centre (BCOC), the Air Ministry Operations Centre and, for standby purposes, at the Air Defence Main Control Centre and Headquarters No. 1 Group. The processed data will also be passed to NORAD over the USA rearward data handling system and this system</ref>

• RCA Communications Data Processor (CDP),<ref name=Gandy>Template:Cite book</ref> as used in the Western Electric Air Force Communications Network (AF DATACOM) of AUTODIN<ref name=Spring1963>Template:Cite journal</ref>Template:Rp
• Western Electric<ref name=Moora>Template:Cite journal</ref> BMEWS Rearward Communications System, a network to link the separate elementsTemplate:R<ref>{{#invoke:citation/CS1|citation

|CitationClass=web }}</ref>Template:Unreliable source? and one of six ADC comm systems: BMEWS Rearward Long-Lines System<ref>Template:Cite report</ref> at CFS Resolution Island<ref name=Mitchell>{{#invoke:citation/CS1|citation |CitationClass=web }}</ref>Template:Unreliable source?<ref>{{#invoke:citation/CS1|citation |CitationClass=web }}</ref> and CFS Saglek,<ref>{{#invoke:citation/CS1|citation |CitationClass=web }}</ref>Template:Unreliable source? (cf. Pole Vault system on the Pinetree Line, White Alice in Alaska,Template:R and to RAF Fylingdales, NARS)

• BMEWS Central Computer and Display Facility (CC&DF)Template:R at Ent AFB (ZI portion of BMEWS),<ref name=NORAD1958 /> with RCA Display Information Processor (DIP)Template:R—DIPS displays were also at the Offutt AFB war room floor and balcony,<ref>Template:Cite AV media</ref> as well as at the Pentagon<ref name=DelPapa>Template:Cite report</ref>

To predict when parts might break down,Template:R the contractor also installed RCA 501 computers<ref>{{#invoke:citation/CS1|citation |CitationClass=web }}</ref> with 32k high-speed memory, 5-76KC 556 bpi 3/4" tape drives, and 200-track random-access LFE drums.Template:Citation needed The initially replaced portions of BMEWS included the Ent CC&DF by the Burroughs 425L Missile Warning System at the Cheyenne Mountain Complex<ref name=GAO1978>{{#invoke:citation/CS1|citation |CitationClass=web }}</ref> (FOC 1 July 1966.)<ref name=DelPapa /> The original Missile Impact Predictors were replaced (IOC on 31 August 1984),<ref name=DelPapa /> and BMEWS systems were entirely replaced by 2001 (e.g., radars were replaced with AN/FPS-120 SSPARS) after Satellite Early Warning Systems had been deployed (e.g., 1961 MIDAS, 1968 Project 949, and 1970 DSP satellites).

Classification of radar systemsEdit

Template:Further Under the Joint Electronics Type Designation System (JETDS), all U.S. military radar and tracking systems are assigned a unique identifying alphanumeric designation. The letters “AN” (for Army-Navy) are placed ahead of a three-letter code.<ref name=EWRS2013>Template:Cite book</ref>

• The first letter of the three-letter code denotes the type of platform hosting the electronic device, where A=Aircraft, F=Fixed (land-based), S=Ship-mounted, and T=Ground transportable.
• The second letter indicates the type of equipment, where P=Radar (pulsed), Q=Sonar, and R=Radio.
• The third letter indicates the function or purpose of the device, where G=Fire control, R=Receiving, S=Search, and T=Transmitting.

Thus, the AN/FPS-49 represents the 49th design of an Army-Navy “Fixed, Radar, Search” electronic device.<ref name=EWRS2013/><ref name=Winkler1997>Template:Cite book</ref>

Early testsEdit

On 2 June 1955, a General Electric AN/FPS-17 "XW-1" radar at Site IX<ref name=Zabetakis>Template:Cite report</ref> in Turkey that had been expedited was completed by the US in proximity to the ballistic missile launch test site at Kapustin Yar in the Soviet Union<ref name=StoneBanner /> for tracking Soviet rockets<ref name=Skolnik>{{#invoke:citation/CS1|citation |CitationClass=web }}</ref> and to demonstrate the feasibility of advanced Doppler processing, high-power system components, and computerized tracking needed for Template:Sic.<ref name=StoneBanner />

The first missile tracked was on 15 June, and the radar's parabolic reflector was replaced in 1958,Template:R and its range was extended from 1000 to 2000 nautical miles<ref>Template:Cite AV media</ref> after the 1957 Gaither Commission identified that because of expected Soviet ICBM development, there would be little likelihood of SAC's bombers surviving since there was no way to detect an incoming attack until the first warhead landed.<ref name=Freeman>Template:Cite news</ref>

BMEWS' General Operational Requirement 156 was issued on 7 November 1957 (BMEWS was designed to go with the active portion of the WIZARD system) and on 4 February 1958; the USAF informed Air Defense Command (ADC) that BMEWS was an "all-out program" and the "system has been directed by the President, has the same national priority as the ballistic missile and satellite programs and is being placed on the Department of Defense master urgency list".<ref>USAF memo to Air Defense Command cited in 1958 NORAD/CONAD Historical Summary, Jan-Jun</ref> By July 1958 after NORAD manning began, ADC's 1954 blockhouse for the Ent AFB command center had inadequate floor space; and Ent's "requirement for a ballistic missile defense system display facility...brought renewed action...for a new command post"<ref name=NORAD1958 /> (the JCS approved the nuclear bunker on 11 February 1959).

Planning and developmentEdit

On 14 January 1958, the US announced its decision to establish a Ballistic Missile Early Warning System<ref name=Chronology>{{#invoke:citation/CS1|citation |CitationClass=web }} (list also at NORAD.mil Template:Webarchive & in 2008 book</ref> with Thule to be operational in 1959—total Thule/Clear costs in a May 1958 estimate were ~$800 million (an October 13, 1958, plan for both estimated completion in September 1960.)<ref name=Wainstein>Template:Cite report</ref> The Lincoln Laboratory's radar at Millstone Hill, Massachusetts, was built and provided data to a 1958<ref>Template:Cite book</ref> for trajectory estimates, e.g., Cape Canaveral missiles, and an adjunct high-power UHF test facility employed the Millstone transmitter to stress-test the components that were candidates for the operational BMEWS.<ref name=StoneBanner /> (A twin of the Millstone Hill radar was dedicated at Saskatchewan's Prince Albert Radar Laboratory on June 6, 1959.)<ref name=StoneBanner /> A prototype AN/FPS-43 BMEWS radar<ref name=BMW /> completed at Trinidad in 1958 went operational on 4 February 1959, the date of an Atlas II B firing from Cape Canaveral Launch Complex 11<ref>{{#invoke:citation/CS1|citation |CitationClass=web }}</ref> (lunar reflection was tested January–June 1960).<ref>{{#invoke:citation/CS1|citation |CitationClass=web }}</ref> On June 30, 1958, NORAD emphasized that the BMEWS could not be considered as a self-contained entity separate from the Nike Zeus, or vice versa.<ref>Template:Cite report (cited by 1958 NORAD/CONAD Historical Summary, Jan-Jun)</ref>

On 18 March 1959, the USAF told the BMEWS Project OfficeTemplate:Where to proceed with an interim facility<ref name=NORAD1959>Template:Cite NORAD Historical Summary</ref>Template:Rp for the "AICBM control center" with an anti-ICBM C³ computer<ref name=NORAD1958B>Template:Cite NORAD Historical Summary</ref>Template:Rp (e.g., for when the USAF WizardTemplate:RTemplate:Rp and/or Army Nike ZeusTemplate:R ABMs became operational), and the basement of the 1954 ADC blockhouse was considered for the interim center.Template:RTemplate:Rp A "satellite prediction computer" could be added to the planned missile warning center if Cheyenne Mountain's "hardened COC slipped considerably beyond January 1962"<ref name=NORAD1959 />Template:Rp (tunneling began in June 1961.) In early 1959 for use at Ent in September 1960, a BMEWS display facility with "austere and economical construction with minimum equipment" was planned in an "annex to the current COC building".<ref name=NORAD1959 /> In late 1959, ARPA openedTemplate:Where the 474L System Program Office,<ref name=GlobalSecurity>{{#invoke:citation/CS1|citation |CitationClass=web }}</ref> and BMEWS' "12th Missile Warning Squadron at Thule...began operating in January 1960."<ref>Template:Cite book</ref> Following a Nike ABM intercept of a test missile, the planned Cheyenne Mountain mission was expanded in August 1960 to "a hardened center from which CINCNORAD would supervise and direct operations against space attack as well as air attack"<ref name=ARDC>Template:Cite report (cited by Schaffel, p. 262)</ref> (NORAD assumed "operational control of all space assets with the formation of" SPADATS in October 1960.)Template:R The 1st Aerospace Surveillance and Control Squadron (1st Aero) was activated at Ent AFB on 14 February 1961; and Ent's Federal Building was completed Template:Circa.

DeploymentEdit

Clear AFS construction began in August 1958Template:R with 700 workersTemplate:R and was completed 1 July 1961,<ref name=Ellensburg>Template:Cite news</ref> and Thule Site J construction began by 18 May 1960,<ref>Template:Cite news</ref> with radar pedestals complete by 2 June.<ref name=Rogers>Template:Cite news</ref> Thule testing began on 16 May 1960,<ref>Template:Cite news</ref> IOC was completed on 30 September,<ref name=Wainstein /> and the initial operational radar transmission was in October 1960Template:R (initially duplex vacuum tube IBM 709s occupied two floors).Template:Citation needed

On 5 October 1960, when Khrushchev was in New York,Template:R radar returns during moonrise at Thule<ref>{{#invoke:citation/CS1|citation |CitationClass=web }}</ref> produced a false alarm. On 20 January 1961, CINCNORAD approved two-second FPS-50 frequency hoping to eliminate reception of echoes beyond artificial satellite orbits.<ref name=StoneBanner /> On 24 November 1961, an AT&T operator failure at their Black Forest microwave station northeast of Colorado Springs<ref>Template:Cite news</ref>Template:Unreliable source? caused a BMEWS communications outage to Ent and OffuttTemplate:Snda B-52 near Thule confirmed the site still remained.<ref>{{#invoke:citation/CS1|citation |CitationClass=web }}</ref>

Training for civilian technicians included a February 1961 RCA class in New Jersey for a Tracking Radar Automatic Monitoring class.<ref>{{#invoke:citation/CS1|citation |CitationClass=web }}</ref> The "Clear Msl Early Warning Stn, Nenana, AK" was assigned to Hanscom Field, Massachusetts, by the JCA on 1 April 1961.<ref name=Mueller>Template:Cite report</ref> By 16 May 1961, Ent's "War Room at NORAD" had a glass map for plotting aircraft and had a "map [that] lights up" to show multiple impact ellipses and times "before the huge missile[s] would burst"<ref name=Pearson>Template:Cite newsTemplate:Dead link</ref> (separate from Ent's BMEWS CC&DF building, the two-story blockhouse had a war room with, left of the main NORAD region display, a BMEWS display map and "threat summary display" with a count of incoming missiles.)<ref>Template:Cite news</ref>Template:Efn The Trinidad Test Site transferred from Rome AFB to Patrick AFB on 1 July 1961 (closed as "Trinidad Air Station" on 1 October 1971)Template:R and the same month, the 1st Aero began using Ent's Space Detection and Tracking System (SPADATS) operation center in building P4's annex<ref>Template:Full citation needed1961–1969 Historical reports from the Squadron on file at the Air Force Historical Research Agency, Maxwell AFB AL, AFHRA Microfilm reel KO363</ref> (Cheyenne Mtn's Space Defense Center became fully operational in 1967.)<ref name=Chronology /> The BRCS undersea cable was cut "presumably by fishing trawlers" in September, October, and November 1961 (the BMEWS teletype and backup SSB substituted);Template:R and in December 1961, Capt. Joseph P. Kaufman was charged "with giving [BMEWS] defense data to ... East German Communists."<ref>Template:Cite news</ref>

BMEWS surveillance wingEdit

The 71st Surveillance Wing, Ballistic Missile Early Warning System, was activated on 6 December 1961, at Ent AFB (renamed 71st Missile Warning Wing on 1 January 1967, at McGuire AFB 21 July 1969 – 30 April 1971).Template:R Syracuse's BMEWS Test Facility at GE's High-Power Radar Laboratory<ref>Template:Cite journal</ref> became the responsibility of Rome Air Development Center on 11 April 1962<ref name=Strain>Template:Cite report</ref> (Syracuse's Eagle Hill Test Annex closed in 1970)Template:R and on 31 July 1962, NORAD recommended a tracking radar station at Cape Clear to close the BMEWS gap with Thule for low-angle missiles (versus those with the 15-65 degree angle for which BMEWS was designed.)<ref name=NORAD1962B>{{#invoke:citation/CS1|citation |CitationClass=web }}</ref> By mid-1962, BMEWS "quick fixes" for ECCM had been installed at Fylingdales Moor, Thule and Cape Clear AKTemplate:R and by June 30, integration of BMEWS and SPADATS at Ent AFB was completed.<ref name=DelPapa /> During the Cuban Missile Crisis, the Moorestown AN/FPS-49 radar on 24 October was "withdrawn from SPADATS and realigned to provide missile surveillance over Cuba."Template:R 1962 "strikes and walkouts" delayed Fylingdales' planned completion from March until September 1963 and on 7 November, the Pentagon BMEWS display subsytem installation was complete.<ref name=DelPapa /> At the end of 1962, NORAD was "concerned over BMEWS' virtual inability to detect objects beyond a range of 1500 nautical miles."Template:R The Moorestown FPS-49 completed a BMEWS "signature analysis program" on scale models by January 1963.<ref name=Det3>Template:Cite report</ref>

Air Defense Command / Aerospace Defense CommandEdit

Operations transferred from civilian contractors (RCA Government Services)Template:RTemplate:Rp to ADC on 5 January 1962<ref name=Newburgh>Template:Cite news</ref> (renamed Aerospace Defense Command in 1968.) Fylingdales became operational on 17 September 1963,<ref>Template:Cite news</ref>Template:R and Site III transferred to RAF Fighter Command on 15 January 1964.<ref> Template:Cite book </ref> Remaining BMEWS development responsibilities transferred to the "Space Track SPO (496L)" when the BMEWS SPO closed on 14 February 1964<ref name=DelPapa />—e.g., the AN/FPS-92 with "66-inch panels"<ref>Template:Cite book</ref> was added to Clear in 1966<ref>Template:Cite news</ref> (last of the five tracking radars),<ref>Template:Cite news</ref> and in 1967, BMEWS modification testing was complete on 15 May, when the system cost totaled $1.259 billion,<ref name=DelPapa /> equivalent to $Template:Format price in Template:Inflation/year.Template:Inflation/fn In 1968, Ent's 9th Division HQ had a Spacetrack/BMEWS Maintenance Section.<ref>{{#invoke:citation/CS1|citation |CitationClass=web }}Template:Unreliable source?Template:Synthesis inline</ref>

In 1975, SECDEF told Congress that Clear would be closed when Cobra Dane and the Beale AFB PAVE PAWS became operational.<ref>Template:Cite report</ref> By 1976, BMEWS included IBM 7094, CDC 6000, and Honeywell 800 computers.<ref>Template:Cite news</ref>

USAF Space CommandEdit

On 1 October 1979, Thule and Clear transferred to Strategic Air Command when ADCOM was broken up<ref name=Johnson>compiled by Template:Cite book</ref> then to Space Command in 1982. By 1981 Cheyenne Mountain had been averaging 6,700 messages per hour<ref>Template:Cite report</ref> compiled via sensor inputs from BMEWS, the JSS, the 416N SLBM "Detection and Warning System, COBRA DANE, and PARCS as well as SEWS and PAVE PAWS" for transmission to the NCA.<ref name=WWMCCS>Template:Cite report</ref> To replace AN/FSQ-28 predictors, a late 1970s plan for processing returns from MIRVs<ref>Template:Cite book</ref> installed in new Missile Impact Predictor computers was complete by September 1984.<ref name=DelPapa /><ref name=AFHindex>{{#invoke:citation/CS1|citation |CitationClass=web }}</ref>

ReplacementEdit

The BMEWS was replaced by the Solid State Phased Array Radar System in 2001.<ref name="Chapman" />

See alsoEdit

Template:Portal

• Main Centre for Missile Attack Warning (Russia)
• Solid State Phased Array Radar System
• List of radars
• List of military electronics of the United States

NotesEdit

Template:Notelist

ReferencesEdit

Template:Reflist

External linksEdit

• US Air Force film
• Both Trinidad test radars & 1957 FPS-50 reflector scale model
• 1961 Thule sketch, FPS-50 wave guides, & "memory and logic unit" Template:Webarchive
• 1961 BMEWS Rearward communications "billboard type" antenna
• construction of a Fylingdale's radome
• "Moorestown's Giant Golf Ball
• Scan newsletter of Site III
• SAC DIP screen with impact ellipses (Reel 2, minute 4:40)
• Eyes of the North
• Flyingdales Rearward Data Room

Template:United States Missile Defense Template:AN/FPS Template:USAF system codes