Blue Joker

Last updated
Blue Joker
Country of origin United Kingdom
Introduced1958
No. built2
TypeAirborne Early Warning
Frequency3.3 GHz
PRF 500 pps
Beamwidth 0.8° horizontal, 2.3° vertical
Pulsewidth1.5 S
RPM6 or 8 rpm
Range120 miles
Azimuth 360°
Power600 kW peak

Blue Joker was an experimental moored balloon-mounted, airborne early-warning radar project developed by the Royal Radar Establishment (RRE) starting in 1953. The idea was to position the radar high in the air in order to extend its radar horizon and allow it to see low-flying aircraft. Ground reflections were filtered out using a moving target indicator (MTI) system. Two examples were built and tested in the late 1950s, but the project was cancelled in 1960 as part of the Linesman/Mediator efforts.

Contents

Development

Basic concepts

During the early 1950s the Royal Air Force was in the midst of deploying its ROTOR radar network based on the AMES Type 80 (Green Garlic) radars. These were powerful S-band radars able to detect high-flying bombers at ranges as great as 250 miles (400 km). However, due to the curvature of the Earth, they were subject to the local radar horizon so low-flying aircraft were not visible until they approached much more closely. In the early 1950s, there was some concern that Soviet aircraft might be able to fly under the radar's coverage. [1]

Some sort of airborne radar system looking down from above would address this. Aircraft, helicopters and balloons were considered for the role. A system using two barrage balloons developed by the Royal Aircraft Establishment (RAE) at RAF Cardington was eventually selected. This was due to the problem of converting the range and angle information provided by the radar to a location on the ground if the exact location of the platform was not known, a problem that didn't exist with balloons because they were moored to a fixed location. [1]

Microwaves have the advantage that they tend to scatter forward at low angles, so the direct reflection off flat ground does not necessarily return enough signal to the radar to overwhelm it, a problem that had plagued the very high frequency radars of the 1940s. However, it was still subject to reflection off of natural corner reflectors like trees and waves. The solution to this problem is to use a form of moving target indication, or MTI. This filters out slowly-moving returns, leaving only those in a certain speed range to be displayed, in this case, aircraft. [1]

The other problem was getting the signal to the ground, a coaxial cable would lose too much signal and waveguides are not easily made flexible or extendable. During this period the RRE had begun experimenting with the transmission of radar signals using microwave relays. This system tapped into the changing voltage being sent to the radar display, the video signal, and sent it to the reflector plate of a reflex klystron. This produced a microwave signal with a varying frequency encoding a frequency modulated version of the video. [2]

Blue Joker

After discussing the concept in 1953 with several manufacturers, in 1954 a contract was signed with Metropolitan-Vickers to develop the system under the rainbow code "Blue Joker". The radar was a fairly conventional model for the era, using a cavity magnetron as the transmitter source and a reflex klystron as a local oscillator in the superheterodyne receiver. [1]

The radar system was housed in a large spherical radome made of Terylene (Dacron) fabric and made rigid by inflating it to 980 pascals (0.142 psi) with a fan at the base of the sphere. The entire assembly massed 1,660 kilograms (3,660 lb). [2] The system originally used two barrage balloons for lift, but a third was later added. Each balloon provided 1,400 kilograms (3,100 lb) of lift and carried the sphere to an altitude of 1,500 metres (4,900 ft). [1]

The signals from the radar were sent to the ground over a datalink manufactured by EMI. Signals from the ground to the radar were sent by modulating a signal into the power cables. The power cables also served double duty as the mooring cables. [2]

Testing

The radar and MTI system were tested in 1956 by mounting the new Type 900 antenna on a Radar, Anti-Aircraft No. 4 Mk. 7 system and towing it to a point near the peak of Y Drum in Wales where it could look down on the Irish Sea over Llanfairfechan. [3] [4] This simulated the view from the balloon. [1]

Two prototypes of the complete airborne system built. The first flight was in May 1958, and a total of 29 flights of 50 hours had been completed by 1959. During trials the radar successfully tracked an approaching Canberra jet bomber, 120 miles away (190 km) [2]

Wind proved to be a major problem for the system, limiting the safe flying speed to 70 knots (130 km/h; 81 mph), but only 30 knots (56 km/h; 35 mph) for handling on the ground. The wind also caused the balloons to lose gas at a rapid rate, in one case losing half the gas over a 40-hour period in a gale. Other issues were the life of the tether cable, the vulnerability to lightning strikes, and the system's poor mobility. [2]

Cancellation

While Blue Joker was being developed, versions of the carcinotron tube were being perfected in the United States. The carcinotron can tune its microwave output over a very wide band, allowing it to match the frequency of any conventional radar system and effectively jam it. It appeared to render radars like ROTOR's Type 80 and the Blue Joker effectively useless. Solutions to the problem were quickly developed, but placing them in service would be very expensive. [5]

The 1957 Defence White Paper suggested that by the mid-1960s an air attack by manned bombers would be unlikely in a battle dominated by ballistic missiles. Through the late 1950s, debate raged about whether to proceed with a new radar network that would not be complete until after this time. [5] In early 1960, Harold Macmillan agreed to fund the "Plan Ahead" network under the condition that work on other early warning radar systems ended. [6] Blue Joker was a victim of this decision; it was cancelled in October 1960. [7]

Description

The antenna was a cylindrical design 8.3 by 2.6 metres (27.2 ft × 8.5 ft), with a gain of 42 dB. It was of asbestos-fibre-reinforced phenolic resin with aluminium stripes glued to the front to act as the reflector surface. It was fed by a slotted waveguide in front. [1]

Since the beam was fairly narrow vertically, it had to maintain its level quite accurately. This was accomplished by mounting it inside a large gyroscopically leveled gimbal system with the antenna on one side and the electronics on the other to balance it out. Small lead weights were used for finer balancing. The system could maintain level within 0.5° when the mooring cable was tilted as much as 30°. [2]

Running vertically through the middle of the gimbal rings was a 20 centimetres (7.9 in) diameter pole that sat in large bearings at the top and bottom of a 9 metres (30 ft) diameter terylene fabric sphere that was inflated by a fan in the base. The bearings allowed the sphere to turn without moving the radar system, which allowed the balloons to move about in the wind without rotating the antenna. The pole also acted as the connection points on the top and bottom for the guy wires that ran to the ground below and the balloons above. The entire assembly massed 1,660 kilograms (3,660 lb). [2]

The ground wire combined the duties of supplying power to the system as well as mooring the entire system. This consisted of a three-core nylon-insulated power cable. It had a linear density of about 0.9 kilograms (2.0 lb) per meter, which used up half of the total lifting capacity of the system. [2] The original two-balloon system later gave way to a three-balloon system, each providing 1,400 kilograms (3,100 lb) of lift when filled with a total of 2,400 cubic metres (85,000 cu ft) of hydrogen. [1]

Related Research Articles

<span class="mw-page-title-main">Microwave</span> Electromagnetic radiation with wavelengths from 1 m to 1 mm

Microwave is a form of electromagnetic radiation with wavelengths shorter than other radio waves but longer than infrared waves. Its wavelength ranges from about one meter to one millimeter, corresponding to frequencies between 300 MHz and 300 GHz, broadly construed. A more common definition in radio-frequency engineering is the range between 1 and 100 GHz, or between 1 and 3000 GHz . The prefix micro- in microwave is not meant to suggest a wavelength in the micrometer range; rather, it indicates that microwaves are small, compared to the radio waves used in prior radio technology.

<span class="mw-page-title-main">Cavity magnetron</span> Device for generating microwaves

The cavity magnetron is a high-power vacuum tube used in early radar systems and subsequently in microwave ovens and in linear particle accelerators. A cavity magnetron generates microwaves using the interaction of a stream of electrons with a magnetic field, while moving past a series of cavity resonators, which are small, open cavities in a metal block. Electrons pass by the cavities and cause microwaves to oscillate within, similar to the functioning of a whistle producing a tone when excited by an air stream blown past its opening. The resonant frequency of the arrangement is determined by the cavities' physical dimensions. Unlike other vacuum tubes, such as a klystron or a traveling-wave tube (TWT), the magnetron cannot function as an amplifier for increasing the intensity of an applied microwave signal; the magnetron serves solely as an electronic oscillator generating a microwave signal from direct current electricity supplied to the vacuum tube.

<span class="mw-page-title-main">Barrage jamming</span>

Barrage jamming is an electronic warfare technique that attempts to blind ("jam") radar systems by filling the display with noise, rendering the broadcaster's blip invisible on the display, and often those in the nearby area as well. "Barrage" refers to systems that send signals in many bands of frequencies compared to the bandwidth of any single radar. This allows the jammer to jam multiple radars at once, and reduces or eliminates the need for adjustments to respond to any single radar.

<span class="mw-page-title-main">Klystron</span> Vacuum tube used for amplifying radio waves

A klystron is a specialized linear-beam vacuum tube, invented in 1937 by American electrical engineers Russell and Sigurd Varian, which is used as an amplifier for high radio frequencies, from UHF up into the microwave range. Low-power klystrons are used as oscillators in terrestrial microwave relay communications links, while high-power klystrons are used as output tubes in UHF television transmitters, satellite communication, radar transmitters, and to generate the drive power for modern particle accelerators.

<span class="mw-page-title-main">Project Echo</span> First passive communications satellite experiment

Project Echo was the first passive communications satellite experiment. Each of the two American spacecraft, launched in 1960 and 1964, were metalized balloon satellites acting as passive reflectors of microwave signals. Communication signals were transmitted from one location on Earth and bounced off the surface of the satellite to another Earth location.

<span class="mw-page-title-main">Pulse-Doppler radar</span> Type of radar system

A pulse-Doppler radar is a radar system that determines the range to a target using pulse-timing techniques, and uses the Doppler effect of the returned signal to determine the target object's velocity. It combines the features of pulse radars and continuous-wave radars, which were formerly separate due to the complexity of the electronics.

Linesman/Mediator was a dual-purpose civil and military radar network in the United Kingdom between the 1960s and 1984. The military side (Linesman) was replaced by the Improved United Kingdom Air Defence Ground Environment (IUKADGE), while the civilian side (Mediator) became the modern public-private National Air Traffic Services (NATS).

<span class="mw-page-title-main">Airport surveillance radar</span> Radar system

An airport surveillance radar (ASR) is a radar system used at airports to detect and display the presence and position of aircraft in the terminal area, the airspace around airports. It is the main air traffic control system for the airspace around airports. At large airports it typically controls traffic within a radius of 60 miles (96 km) of the airport below an elevation of 25,000 feet. The sophisticated systems at large airports consist of two different radar systems, the primary and secondary surveillance radar. The primary radar typically consists of a large rotating parabolic antenna dish that sweeps a vertical fan-shaped beam of microwaves around the airspace surrounding the airport. It detects the position and range of aircraft by microwaves reflected back to the antenna from the aircraft's surface. The secondary surveillance radar consists of a second rotating antenna, often mounted on the primary antenna, which interrogates the transponders of aircraft, which transmits a radio signal back containing the aircraft's identification, barometric altitude, and an emergency status code, which is displayed on the radar screen next to the return from the primary radar.

<span class="mw-page-title-main">Microwave transmission</span> Transmission of information via microwaves

Microwave transmission is the transmission of information by electromagnetic waves with wavelengths in the microwave frequency range of 300 MHz to 300 GHz of the electromagnetic spectrum. Microwave signals are normally limited to the line of sight, so long-distance transmission using these signals requires a series of repeaters forming a microwave relay network. It is possible to use microwave signals in over-the-horizon communications using tropospheric scatter, but such systems are expensive and generally used only in specialist roles.

Frequency agility is the ability of a radar system to quickly shift its operating frequency to account for atmospheric effects, jamming, mutual interference with friendly sources, or to make it more difficult to locate the radar broadcaster through radio direction finding. The term can also be applied to other fields, including lasers or traditional radio transceivers using frequency-division multiplexing, but it remains most closely associated with the radar field and these other roles generally use the more generic term "frequency hopping".

COHO, short for Coherent Oscillator, is a technique used with radar systems based on the cavity magnetron to allow them to implement a moving target indicator display. Because the signals are only coherent when received, not transmitted, the concept is also sometimes known as coherent on receive. Due to the way the signal is processed, radars using this technique are known as pseudo-coherent radar.

<span class="mw-page-title-main">Sutton tube</span>

Sutton tube was the name given to the first reflex klystron, developed in 1940 by Robert W. Sutton of Signal School group at the Bristol University. The Sutton tube was developed as a local oscillator for the receiver of 10cm microwave radar sets. Due to its geometry and long drift space, it suffered from mode jumping through the tuning range. For this reason, from late 1941 onward, it was replaced in many sets by the Western Electric 707A.

<span class="mw-page-title-main">AI Mark VIII radar</span> Type of air-to-air radar

Radar, Aircraft Interception, Mark VIII, or AI Mk. VIII for short, was the first operational microwave-frequency air-to-air radar. It was used by Royal Air Force night fighters from late 1941 until the end of World War II. The basic concept, using a moving parabolic antenna to search for targets and track them accurately, remained in use by most airborne radars well into the 1980s.

<span class="mw-page-title-main">AMES Type 82</span> Cold War-era British medium-range 3D radar

The AMES Type 82, also widely known by its rainbow codename Orange Yeoman, was an S-band 3D radar built by the Marconi Company and used by the Royal Air Force (RAF), initially for tactical control and later for air traffic control (ATC).

<span class="mw-page-title-main">RX12874</span> Military radar detector

RX12874, also known as the Passive Detection System (PDS) and by its nickname "Winkle", was a radar detector system used as part of the Royal Air Force's Linesman/Mediator radar network until the early 1980s. Winkle passed out of service along with the rest of the Linesman system as the IUKADGE network replaced it.

<span class="mw-page-title-main">AMES Type 80</span> Cold War-era British early warning radar

The AMES Type 80, sometimes known by its development rainbow code Green Garlic, was a powerful early warning (EW) and ground-controlled interception (GCI) radar developed by the Telecommunications Research Establishment (TRE) and built by Decca for the Royal Air Force (RAF). It could reliably detect a large fighter or small bomber at ranges over 210 nautical miles, and large, high-flying aircraft were seen out to the radar horizon. It was the primary military ground-based radar in the UK from the mid-1950s into the late 1960s, providing coverage over the entire British Isles.

<span class="mw-page-title-main">AMES Type 85</span> Cold War-era British early warning radar

The AMES Type 85, also known by its rainbow code Blue Yeoman, was an extremely powerful early warning (EW) and fighter direction (GCI) radar used by the Royal Air Force (RAF) as part of the Linesman/Mediator radar network. First proposed in early 1958, it was eleven years before they became operational in late 1968, by which time they were already considered obsolete. The Type 85 remained the RAF's primary air defense radar until it was replaced by Marconi Martello sets in the late-1980s as part of the new IUKADGE network.

The AMES Type 84, also known as the Microwave Early Warning or MEW, was a 23 cm wavelength early warning radar used by the Royal Air Force (RAF) as part of the Linesman/Mediator radar network. Operating in the L-band gave it improved performance in rain and hail, where the primary AMES Type 85 radar's performance dropped off. It operated beside the Type 85 and RX12874 in Linesman, and moved to the UKADGE system in the 1980s before being replaced during UKADGE upgrades in the early 1990s.

The AR-3D was a military air traffic control and early warning radar developed by Plessey and first produced in 1975. It used a pencil beam and simple frequency scanning system known as "squint scan" to produce a low-cost 3D radar system that was also relatively mobile. About 23 were produced in total and found sales around the world into the early 1980s.

<span class="mw-page-title-main">Wireless Set Number 10</span> Worlds first microwave relay telephone system

The British Army's Wireless Set, Number 10, was the world's first multi-channel microwave relay telephone system. It transmitted eight full-duplex (two-way) telephone channels between two stations limited only by the line-of-sight, often on the order of 25 to 50 miles. The stations were mounted in highly mobile trailers and were set up simply by aiming the two parabolic antennas on the roof at the next station. The system could be extended into a relay by connecting trailers together, or using existing landlines to connect separated trailers.

References

Citations

  1. 1 2 3 4 5 6 7 8 Smith 1985, p. 461.
  2. 1 2 3 4 5 6 7 8 Smith 1985, p. 462.
  3. "Pictures of transport and assembly of the Blue Joker equipment in 1956 at Drum". Archived from the original on 2017-05-28.
  4. Pictures of the remains of the Drum test site in 2011
  5. 1 2 Spinardi 2016, p. 246.
  6. Spinardi 2016, p. 248.
  7. Clarke 2012, p. 113.

Bibliography