Bloodhound (missile)

The Bristol Bloodhound is a British ramjet powered surface-to-air missile developed during the 1950s. It served as the UK's main air defence weapon into the 1990s and was in large-scale service with the Royal Air Force (RAF) and the forces of four other countries.

Bloodhound Mk 1
A Bloodhound missile at the RAF Museum, Hendon, London.
TypeSurface-to-air missile
Place of originUnited Kingdom
Service history
In service1958 (MK 1)/1964 (MK 2) - 1991
Used bySee operators
Production history
Designed1950s
ManufacturerBristol Aeroplane Co.
No. built783
VariantsSee variants
Specifications (MK 2)
MassOverall: 2,270 kg (5,000 lb)
LengthOverall: 8.46 m (27 ft 9 in)
DiameterMain body 54.6 cm (1 ft 9.5 in)
WingspanOverall: 2.83 m (9 ft 3 in)
WarheadContinuous-rod warhead
Detonation
mechanism
Proximity fuze

EngineRamjets, 4× solid fuel boosters
Operational
range
52 km (32 mi) (MK 1)
190 km (120 mi) (MK2)
Maximum speed Mach 2.7
Guidance
system
Semi-active radar homing
Steering
system
Control surfaces
Launch
platform
Fixed installation

Part of sweeping changes to the UK's defence posture, the Bloodhound was intended to protect the RAF's V bomber bases to preserve the deterrent force from attacking bombers that made it past the Lightning interceptor force. Bloodhound Mk. I entered service in December 1958, the first British guided weapon to enter full operational service. This was part of Stage 1 upgrades to the defensive systems, in the later Stage 2, both Bloodhound and the fighters would be replaced by a longer-range missile code named Blue Envoy. When this was ultimately cancelled in 1957, parts of its design were worked into Bloodhound Mk. II, roughly doubling the range of the missile. The Mk. I began to be replaced by the Mk. II starting in 1964. Mk. II performance was such that it was also selected as the interceptor missile in the Violet Friend ABM system, although this was ultimately cancelled.

The Bloodhound Mk. II was a relatively advanced missile for its era, roughly comparable to the US's Nike Hercules in terms of range and performance, but using an advanced continuous-wave semi-active radar homing system, offering excellent performance against electronic countermeasures and low-altitude targets. It also featured a digital computer for fire control that was also used for readiness checks and various calculations. It was a relatively large missile, which limited it to stationary defensive roles similar to the Hercules or the Soviets' S-25 Berkut, although Sweden operated its Bloodhounds in a semi-mobile form.

Bloodhound shares much in common with the English Electric Thunderbird, including some of the radar systems and guidance features. Thunderbird was smaller and much more mobile, seeing service with the British Army and several other forces. The two missiles served in tandem for some time, until the shorter-range role of the Thunderbird was replaced by the much smaller and fast-acting BAC Rapier starting in 1971. Bloodhound's longer range kept it in service until the threat of bomber attack by the Soviet Union was deemed to have disappeared with the dissolution of the union in 1991. The last Mk. II missile squadron stood down in July 1991, although Swiss examples remained operational until 1999.

History

Early SAM development

During the late stages of World War II, the British armed forces began the development of surface-to-air missiles (SAMs), or as they became known in the UK, surface-to-air guided weapons (SAGW). The Royal Navy was primarily interested in weapons to counteract Luftwaffe bombers dropping glide bombs, which had been used with great effectiveness during the invasion of Italy, and looking toward countering the kamikaze threat in the Pacific. The British Army was interested in a longer-ranged system to supplant or even replace their anti-aircraft artillery. The Royal Air Force was largely uninterested at this point, and put their effort into air-to-air missiles.

From these different needs, two experimental SAGW systems emerged, the Navy's Fairey Stooge and Army's Brakemine. Stooge was a low-performance system, more of a drone aircraft than a missile, which had to be manually guided in front of approaching aircraft using radio control and then detonated by the operator. This limited it to daytime visual range and good weather, neither of which was satisfying. In contrast to Stooge, Brakemine was a more modern concept. While it offered only marginally better range than Stooge, its beam riding guidance was highly automated and allowed the missile to fly directly at its targets at high speed in any conditions, day or night.

Looking to the future, the Navy saw a need to counter jet-powered aircraft, demanding a much higher-performance system. In 1944, the Navy formed the "Guided Anti-Aircraft Projectile Committee", or GAP Committee, to consider such a design. The GAP team suggested combining the Navy's new Type 909 radar with a new missile to produce a Brakemine-like system but with considerably higher accuracy and much longer range. This was initially known as LOPGAP, for Liquid-Oxygen and Petrol, the proposed fuel.

In January 1947, the new Navy design was given the name Seaslug. Around the same time, an effort was underway to centralise all guided missile development at the Royal Aircraft Establishment's (RAE) new Guided Weapons Department. They took over LOPGAP development from the Navy, as well as using up most existing Stooge and Brakemine systems to gain familiarity with the needs of missile testing. They also issued a requirement for the Army and Air Force for a very long-range weapon to protect important installations like airfields and cities. This became the "Red Heathen" concept, with a desired range on the order of 100,000 yards (91 km).

Seaslug and Red Heathen

During a review of the RAE's work by the Defence Research Policy Committee (DRPC) in March 1948, a lack of manpower at the RAE was a serious issue and Seaslug was downgraded in importance in favour of Red Heathen. Around the same time, the Army began to express doubts about the Red Heathen as it became clear that the beam riding guidance systems of the early experimental missiles did not work at long range.[lower-alpha 1] They suggested Seaslug might be a good interim development.

After considerable debate, in September 1948 Seaslug was restarted as "insurance" against problems in Red Heathen, and in 1949, moved to "top priority". A development contract was signed with Armstrong Whitworth lead development, and the Project 502 industry group was organized in 1949 to produce it.[1] The DRPC suggested downgrading Red Heathen to use a missile with performance roughly equal to Seaslug, but replacing its guidance with a semi-active radar homing system which was more suitable for development of a long-range system in the future. English Electric continued development of this "new" Red Heathen. Later, looking for a second approach to the requirement, using a ramjet instead of a rocket motor, the RAE approached de Havilland, but they declined due to workload. The RAE then turned to Bristol Aerospace, signing an agreement late in 1949 for "Red Duster",[2] which Bristol referred to as "Project 1220".[3] Armstrong, Bristol and EE were now all working on different approaches to the same basic requirement. Ferranti was brought on to begin development of the new radars and guidance systems.[2]

Before long, the two Red Heathen entries began to diverge, and the two designs were given their own rainbow codes; EE's design became "Red Shoes",[4] and Bristol's became "Red Duster".[3] Bristol's efforts were fairly similar to EE's in most ways, although it was somewhat less mobile while offering somewhat better range.[3]

The Stage Plan

After the end of the Second World War, UK air defences were run down, on the assumption that it would be at least a decade before another war started. However, the Soviet atomic bomb test of 1949 forced a re-evaluation of that policy, and UK defence planners started studying the problems of building a more integrated air defence network than the patchwork of WWII expediencies.

The Cherry Report called for a reorganisation of existing radars under the ROTOR project along with new control centres to better coordinate fighters and anti-aircraft guns. This was strictly a stop-gap measure however; over the longer term there would be a requirement for deployment of new long-range radars in place of the Chain Home systems from the war, construction of command and control sites able to survive a nuclear attack, interceptors of ever-increasing performance, and anti-aircraft missiles and guns to provide a last-ditch defence.

The missile portion was the newest and least understood technology. In order to deploy quickly and gain experience with these systems, the "Stage Plan" was developed. "Stage 1" called for missiles based on a LOPGAP/Seaslug-type missile with a range of only 20 miles with capabilities against subsonic or low-supersonic attacking aircraft, which were assumed to be at medium or high altitudes. The original long-range Red Heathen concept then became Stage 2, aiming to replace the Stage 1 design in the 1960s[5] The Stage 1 missile would be based on LOPGAP.[6]

Development

The RAE suggested the use of a ramjet for power as it offered better fuel economy. Bristol had only passing experience with this engine design, so they began a long series of tests to develop it. As the ramjet only operates effectively at high speeds over Mach 1, Bristol built a series of testbed airframes to flight-test the engines. The first, JTV-1,[lower-alpha 2] resembled a flying torpedo with the ramjets fitted to the end of the cruciform rear fins. Early problems were ironed out and the JTV series was the first British ramjet powered aircraft to operate continually at supersonic speeds.[7]

Once the JTV testing started to proceed, Bristol studied a series of airframe designs. The first was a long tube with an intake at the front, and four delta-shaped fins arranged near the front of the fuselage. The intake and wings give it some resemblance to the English Electric Lightning, albeit with a long tube sticking out of the aft end. This arrangement left little internal room for fuel or guidance, as the tube ran down the centre of the entire fuselage. A second design was similar, but used mid-mounted fins of reverse-delta shape (flat at the front) with small intakes at their roots. The performance of these intakes was not well understood, and considered risky. The final design was essentially a small aircraft, with mid-set trapezoidal wings and four small swept wing fins at the extreme rear. In this version, two engines were mounted on the wing tips, similar to the mounting used on the JTV series and thus better understood.[7]

One unique feature of the new design was the aerodynamic control system known as "twist and steer". Typical large missile designs use control surfaces at the tail mounted in-line with symmetric wings mounted near the fuselage midpoint. The control surfaces tilt the missile relative to its direction of travel, causing the wings to become non-symmetrical relative the airflow, generating lift that turns the missile. Bristol was concerned that the angles needed to generate the required lift using this method would be too great for the engines intakes to deal with, so it adopted the twist and steer system, first experimented with on the war-era Brakemine project.

In this system the four cropped-delta surfaces at the tail were fixed and used only for stability, not control. Directional control was provided though two large mid-mounted wings which could be rotated independently to large angles. The guidance system rotated the wings in opposite directions to roll the missile until the wings were perpendicular to the target, and then rotated them in the same direction to provide lift in the required direction. This meant that the wings could be rotated to the angles required to generate large amounts of lift, without rotating the missile body itself. This kept airflow in the direction of the missile body, and thus the engine intakes, as well as greatly reducing the drag caused by the tilting of the fuselage across the relative wind. The long, thin fuselage offered very low rotational inertia, conferring excellent homing performance in the last few seconds. The engines were mounted above and below these wings on short extensions.[8]

In the initial designs, a single very large solid fuel booster launched the missile off its launcher and powered it to speeds where the ramjets could take over.

Flight testing

In 1952 the design was accepted by the Combined United Kingdom/Australia Committee for Trials. A prototype of the new layout was built and flown in Wales as the 14-scale XTV-1, powered by three 5-inch boosters strapped together. This demonstrated that the overall length with the booster attached would be a significant problem in the field.

In response, the original booster was re-designed as a series of four smaller rockets designed to "wrap around" the missile fuselage. This layout was tested on the 13 scale XTV-2, the full-sized but unpowered XTV-3 that tested the new boosters, and finally the full-sized and powered XTV-4. The final modification, first tested on the XTV-3, was to replace the four rear fins with two larger ones, which allowed the four booster motors to be mounted on a common ring, ensuring they separated in different directions. This resulted in the definitive XTV-5.[8]

As the design matured, the engine requirements were finalized. The resulting Bristol Thor was originally designed in conjunction with Boeing, which had extensive experience with the similar engines of the BOMARC missile. Testing of the prototype production versions, known as XRD (eXperimental Red Duster), moved to the Woomera range in South Australia in mid-1953. These proved very disappointing due to ramjet problems, which were traced to the use of a flare as an ignition source inside the engine. This was replaced with an igniter design provided by the National Gas Turbine Establishment and the problems were quickly sorted out. Firings against GAF Jindivik target aircraft started in 1956,[3] and eventually 500 tests of all of the designs were completed before it entered service.[9]

Guidance was semi-automatic, with the targets initially identified by existing early warning radar sites and then handed off to the Bloodhound sites for local detection and attack. This was handled by the truck-mounted Type 83 "Yellow River" pulse radar system that could be fairly easily jammed and was vulnerable to ground "clutter", thus degrading low-level capability.

By the time Bloodhound was ready for deployment, the solid-fuelled Red Shoes, now known as the English Electric Thunderbird, was proving successful and the British Army dropped its orders for the Bloodhound in favour of the Thunderbird. The Bloodhound Mk 1 entered British service in 1958, and was selected for the Royal Australian Air Force (RAAF) in November of that year. Deployment of the Bloodhound Mk. I began in 1958, initially to provide protection for the RAF's V bomber bases. Australian deployments started in January 1961.

Although the Bloodhound was successful technically, Government auditors found that Ferranti had made far larger profits than projected from the Bloodhound I contract. Sir John Lang chaired an inquiry into the matter. Ferranti Chairman, Sebastian de Ferranti, agreed to pay back £4.25 million to the government in 1964.[10]

Mark II

Bloodhound Mk II missiles deployed to Germany for exercise REFORGER '82.

By 1955 it appeared that the Stage 2 missile, originally known as Green Sparkler but now as Blue Envoy, was too far beyond the state of the art to be able to enter service before the Thunderbird and Bloodhound became obsolete. However, the much improved continuous wave radar systems being developed for the same project were progressing well. In order to address the performance gap due to the delays, interim (or vulgar) Stages were added to the Stage plan. "Stage 1+12" combined a slightly upgraded Thunderbird with radar technology from Blue Envoy, while "Stage 1+34" would do the same to Bloodhound.[11]

In 1957 the entire Stage concept was abandoned as part of the 1957 Defence White Paper. The Paper argued that the Soviets would move their strategic forces to ballistic missiles and that the likelihood of an air attack solely by bombers would be increasingly unlikely. An attack by bombers would simply signal that missiles were also on their way. In this case, defending the V bombers against air attack did nothing; the only way they could survive would be to launch to holding areas on any suggestion of any sort of attack. In this case, there was no point trying to defend the bomber bases, and Blue Envoy was not needed.

Its cancellation caught Bristol by surprise, and their missile division, Bristol Dynamics, had no other projects to fall back on. Bristol engineers sharing a taxi with their Ferranti counterparts hatched a new plan to adopt the Blue Envoy ramjets and radars to a lengthened Bloodhound, and submitted this for study. The proposal was accepted, producing the Bloodhound Mk. II.

The Mk. II featured a more powerful Thor engine based on changes investigated in Blue Envoy. The increased power allowed the weights to increased, and to take advantage of this the fuselage was stretched to allow more fuel storage. These changes dramatically extended range from about 35 to 80 kilometres (22 to 50 mi), pushing the practical engagement distance out to about 50 kilometres (31 mi) (although detected at a longer range, the missile takes time to travel to its target, during which the target approaches the base).[12]

The Mk. II was guided by either the Ferranti Type 86 "Firelight" radar for mobile use, or the larger fixed-emplacement Marconi Type 87 "Scorpion". In addition to its own illumination and tracking antennas, the Scorpion also added one of the receiver antennas out of a Bloodhound missile body onto the same antenna framework. This antenna was used to determine what the missile's own receiver was seeing, which was used for jamming detection and assessment. The new radars eliminated problems with ground reflections, allowing the missile to be fired at any visible target, no matter how close to the ground. Combined with the new engines, the Mk. II had an extended altitude performance between 150 and 65,000 feet (46 and 19,812 m).

The use of a CW radar presented a problem for the semi-automatic guidance system. Continuous wave radar systems rely on the Doppler effect to detect moving targets, comparing returned signals to the radar signal being broadcast, and looking for any shift in frequency. However, in the Bloodhound's case the missile was moving away from the reference signal as fast, or faster, than the target would be approaching it. The missile would need to know the velocity of the target as well as its own airspeed in order to know what frequency to look for. But this information was known only to the radar station on the ground, since the missile did not broadcast any signals of its own.

To solve this problem, the radar site also broadcast an omnidirectional reference signal that was shifted to the frequency that the missile's receiver should be looking for, taking into account both the target and missile speed. Thus the missile only had to compare the signal from its nose-mounted receiver with the signal from the launch site, greatly simplifying the electronics.[13]

Many of the calculations of lead, frequency shifting, and pointing angles for the radars were handled by the custom-built Ferranti Argus computer. This machine would later go on to be a successful industrial control computer which was sold all over Europe for a wide variety of roles.[14]

The Mk. II started tests in 1963 and entered RAF service in 1964. Unlike the Mk. I that had limited performance advantages compared to the Thunderbird, the Mk. II was a much more formidable weapon, with capabilities against Mach 2 aircraft at high altitudes. Several new Bloodhound bases were set up for the Mk. II, and some of the Mk. I bases were updated to host the Mk. II.

There was an export version planned, Bloodhound 21, that had less sophisticated electronic countermeasures equipment.[15]

Further developments

The planned Mk. III (also known as RO 166) was a nuclear warhead-equipped Mk. II with a longer range - around 75 miles (121 km) - achieved with improved ramjet engine and larger boosters. This was also to be the interceptor for the Violet Friend anti-ballistic missile system, which added a radio control link to allow the missile to be guided into the rough interception area while the enemy warhead was still too far away for the Type 86 radar to pick up. The project, one of several adaptations of existing British missiles to carry tactical nuclear devices, was cancelled in 1960.

The Mk. IV was a cancelled mobile version, based on Swedish Army field experience.

Operational deployments

Bloodhound as used by the Royal Australian Air Force from 1963 with No. 30 Squadron in Darwin, Australia

In 1956, Second World War Battle of Britain ace, Wing Commander Frederick Higginson DFC DFM was recruited and placed in charge of the new Guided Missile Defence group inside Bristol Aircraft, charged with sales and service of the new systems. Higginson was awarded an OBE in 1963 for the overseas sales that Bloodhound gained, and promoted to the board of Bristol Aircraft in the same year.[16]

The initial Bloodhound Mk. I deployment consisted of nine missile sites: RAF Dunholme Lodge, RAF Watton, RAF Marham, RAF Rattlesden, RAF Woolfox Lodge, RAF Carnaby, RAF Warboys, RAF Breighton, RAF Woodhall Spa[17] and RAF Misson with a trial site at RAF North Coates.[18] The primary reason for these sites being chosen was the defence of the nearby V bomber stations.

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Royal Air Force Bloodhound Mk. 1 missile sites
Operational missile site

Australian deployments started with No. 30 Squadron RAAF at RAAF Base Williamtown in January 1961. A detachment formed in Darwin in 1965. By 1968, the Bloodhound Mk. I missiles were obsolete, and both elements of the squadron had been disbanded by the end of November 1968.

Swiss deployments started in 1964, and by 1967 six sites were operational with a total of nine firing units. These remained operational until 1999 when they were removed from service, and one of the sites (at Gubel) was declared a national historical property.[19]

After the RAF passed the nuclear deterrent role to the Royal Navy in 1970, all Bloodhound systems within the UK were withdrawn and either stored or transferred to RAF Germany for airfield defence with No. 25 Squadron. The possibility of low-level sneak attack by bombers or cruise missiles led to a reappraisal of UK air defences, resulting in No. 85 Squadron forming at West Raynham on 18 December 1975.

With deployment of the Rapier missile to Germany, Bloodhounds were returned to England in 1983 and were in operation at four additional sites, Bawdsey, Barkston Heath, Wyton and Wattisham. These installations used both the "fixed" type 87 radar (Marconi Scorpion) and the "mobile" Type 86 radars (Ferranti Firelight) of their German deployments, with some being mounted on a 30-foot tower to improve visibility and reduce ground reflections. In 1990 as the Cold War wound down the remaining missiles were concentrated at West Raynham and Wattisham with plans to operate them until 1995, but these were later removed in 1991.

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Royal Air Force Bloodhound Mk. 2 missile sites
Operational missile site


In Southeast Asia, the Bloodhound was deployed with the RAF No. 65 Squadron based at RAF Seletar, Singapore as part of the RAF Far East Air Force, and with 33 Squadron at RAAF Butterworth. With the withdrawal of British military forces based in Singapore (under the UK's East of Suez policy) announced in 1968, Singapore bought the entire Bloodhound assets of No. 65 Sqn. and established the Singapore Air Defence Command's 170 Squadron. The squadron was disbanded and its missiles retired at an official ceremony in March 1990.

Basic description

Before-and-after detonation of a K11A1 continuous rod warhead intended for Bloodhound Mk.2

The main missile is a long cylinder of magnesium frames and aluminium alloy skin with a prominent ogive nose cone at the front and some boat-tailing at the rear. Small aluminium-covered wooden cropped-delta wings are mounted midpoint, providing pitch and roll control by pivoting in unison or independently with additional steering provided by differential fuel feed to each of the ram jets. Two smaller rectangular fixed surfaces were mounted in-line with the main wings, almost at the rear of the missile.[9]

The boost engines are held together as a single assembly by a metal ring at the rear of the missile. Each motor has a small hook on the ring as well as similar one at the front holding it to the missile body. After firing, when the thrust of the rockets falls below the thrust of the now-lit ramjets, the boosters slide rearward until the front hook disengages from the missile body. The boosters are then free to rotate around their attachment to the metal ring, and are designed to rotate outward, away from the fuselage. In action, they fold open like the petals on a flower, greatly increasing drag and pulling the entire four-booster assembly away from the missile body.[20][21]

Small inlets on the roots of the stub wings holding the engines allow air into the missile body for two tasks. Two ram air turbines driving turbopumps generate hydraulic power for the wing control system, and a fuel pump that feeds the engines. Smaller inlet tubes provide ram air to pressurize the fuel tanks. Kerosene fuel is held in two large rubber bag tanks in bays either side of the wing bay where the wings are attached. Electrical power was provided by a molten salt battery. At room temperature, this would be inert and suitable for long-term storage without degradation, but was heated to its working temperature by a pyrotechnic heat source ignited at launch.[9]

Although in tests the Bloodhound had executed direct hits on target bombers flying at 50,000 feet (15,000 m),[22] Mark II production models, in common with many air-to-air and surface-to-air missiles of that period and after, had a proximity fuzed continuous rod warhead (known as the K11A1) designed to destroy attacking aircraft without requiring a direct hit.[23][24][25]

Variants

Mk I

  • Length : 7.7 m
  • Launch Weight : 2,000 kg
  • Warhead: 200 lb (91 kg), continuous-wave radar proximity fuse
  • Range : 28 nmi (52 km; 32 mi)
  • Max. Speed : Mach 2.2
  • Propulsion
    • Main : 2× Bristol Thor ramjet engines
    • Booster : 4× Gosling booster rockets
    • Navigation systems were designed by Desmond Sheriff
One of the two Bristol Thor ramjet engines of a Bloodhound missile
Manufacturer tag of Bristol Thor found near the exhaust end of the Thor ramjet engine


Mk II

  • Length : 8.45 m
  • Launch Weight :
  • Warhead : 395 lb (179 kg), pulse radar proximity fuse
  • Range : 100 nmi (190 km; 120 mi)
  • Max. Speed : Mach 2.7
  • Propulsion
    • Main : 2× Thor ramjet engines (Improved)
    • Booster : 4× Gosling booster rockets

The acceleration of the Mk. II can be gauged from the data on an information board at the Bristol Aeroplane Company Museum at Kemble Airfield, Kemble, Gloucestershire, where a complete Bloodhound can be seen. The Mark of Bloodhound this data refers to is not given but is presumably the Mark II since the top speed of the Mk. I is Mach 2.2: "By the time the missile has just cleared the launcher it is doing 400 mph. By the time the missile is 25 feet from the launcher it has reached the speed of sound (around 720 mph). Three seconds after launch, as the four boost rockets fall away, it has reached Mach 2.5 which is roughly 1,800 mph"

Mk III

The planned Mk III (also known as RO 166) was a Mark II with 6 kiloton nuclear warhead and a range of around 125 mi (201 km) achieved with an improved ramjet engine and bigger boosters. The project, one of several adaptations of existing British missiles to carry tactical nuclear devices, was cancelled in 1960. There is evidence that the intention was to "poison" the warheads of nuclear weapons carried by an attacking force via the neutron flux emitted by the warhead.[26]

Mk IV

This would have been a mobile version of Bloodhound.

Operators

 Australia
 Myanmar
60 units supplied by Singapore.[27][28][29]
 Singapore
 Sweden
  • Swedish Air Force
    • Rb 65: Swedish military designation of Mk I
    • Rb 68: Swedish military designation of Mk II
    • Svea Wing (F 8) in Barkaby had two missile squadrons with Rb 68
    • Scania Wing (F 10) in Ängelholm had one missile squadron with Rb 68
    • Kalmar Wing (F 12) in Kalmar had one missile squadron with Rb 68
    • Bråvalla Wing (F 13) in Norrköping had one missile squadron with Rb 68
    • Blekinge Wing (F 17) in Ronneby had one missile squadron with Rb 68
  Switzerland
 United Kingdom

Preserved examples

Australia
Germany
  • Royal Air Force (RAF) Museum Laarbruch. Weeze
Singapore
Sweden
Switzerland
United Kingdom

See also

Notes

  1. Beam riding missiles have the disadvantage of not being able to "lead" their target unless a second radar beam is used, as in Nike Ajax. They also have the problem that radar signals spread out with increasing distance, making the missile increasingly inaccurate at longer ranges. Which of these two issues, or possibly both, is the reason for this switch is not mentioned in available sources.
  2. The RAE had renamed the LOPGAP "RTV-1" for Rocket Test Vehicle, so Bristol's JTV for Jet Test Vehicle was an obvious choice.

References

Citations

  1. Twigge 1993, p. 28.
  2. Twigge 1993, p. 17.
  3. "Bloodhound." Archived 9 November 2007 at the Wayback Machine skomer.u-net.com. Retrieved: 14 May 2011.
  4. "Red Shoes." Archived 9 November 2007 at the Wayback Machine skomer.u-net.com. Retrieved: 14 May 2011.
  5. "The Stage Plan." Archived 5 July 2013 at the Wayback Machine skomer.u-net.com. Retrieved: 14 May 2011.
  6. Smith 1965, p. 101.
  7. King 1959, p. 431.
  8. King 1959, p. 434.
  9. King 1959, p. 435.
  10. "Ferranti timeline, 1964." Archived 3 October 2015 at the Wayback Machine mosi.org.uk. Retrieved: 14 May 2011.
  11. "Bristol Blue Envoy long-range guided missile." Archived 12 April 2012 at the Wayback Machine skomer.u-net.com. Retrieved: 14 May 2011.
  12. "PRO document AIR 20/10625" (compares ranges of UK missile systems). Archived 11 November 2007 at the Wayback Machine skomer.u-net.com. Retrieved: 14 May 2011.
  13. Barrett, Dick. "The Radar Pages, Bloodhound: Life in the Old Dog." Royal Air Force Year Book 1990. Retrieved: 14 May 2011.
  14. Jonathan Aylen (February 2008). ""Bloodhound on my Trail" - Ferranti's adaptation of military hardware to process control computer" (PDF). University of Manchester. Retrieved 3 July 2014.
  15. "Export Sales Brochure: Bloodhound 21 Weapons System." braw.co.uk. Retrieved: 14 May 2011.
  16. "Obituary: Wing Commander F. W. Higginson, OBE, DFC, DFM, wartime fighter ace." The Times, 14 February 2003. Retrieved: 14 May 2011.
  17. "SQN Histories 221-225_P".
  18. Catford, Nick. "Rattlesden Mk. 1 Bloodhound Missile Site." subbrit.org.uk, 16 May 2008. Retrieved: 14 May 2011.
  19. "Bristol Bloodhound." Archived 10 December 2008 at the Wayback Machine wingweb.co. Retrieved: 14 May 2011.
  20. King 1959, p. 436.
  21. "From All Quarters: Britain's Missiles (Image of Bloodhound test, with booster separation)". Flight: 242. 28 August 1953.
  22. Bud 1999, p. 94.
  23. The National Archives, London. DEFE 15/2399
  24. The National Archives, London. AVIA 6/18981
  25. Cocroft and Thomas (Barnwell) 2003, p. 159.
  26. Bud 1999 Page 99
  27. Selth, Andrew (2002): Burma's Armed Forces: Power Without Glory, Eastbridge. ISBN 1-891936-13-1
  28. "Selth, Andrew (2000): Burma's Order of Battle: An Interim Assessment. ISBN 0-7315-2778-X". Archived from the original on 14 September 2009. Retrieved 29 November 2014.
  29. IISS The Military Balance 2007
  30. "Qam Aircraft Collection". Archived from the original on 29 October 2013. Retrieved 27 July 2013.

Bibliography

  • "Bloodhound: The SAGW System of the Royal Air Force." Flight International, 23 October 1959, pp. 431–438.
  • Bud, Robert. Cold War, Hot Science: Applied Research in Britain's Defence Laboratories, 1945–1990. London: Science Museum, 2002, First edition 1999. ISBN 978-1-900747-47-9.
  • Cocroft, Wayne and Roger J. C. Thomas. "The response — air defence". In Barnwell, P. S. Cold War Building for Nuclear Confrontation 1946–1989. Swindon, UK: English Heritage, 2003. ISBN 978-1-873592-81-6.
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