Anti Artillery Radar - ARTHUR (acronym for "Mine Hunting Radar") is an anti-battery radar system originally designed for and supporting Norwegian and Swedish forces by Ericsson Microwave Systems in Sweden and Norway. It is also used by the British Army, under the name mobile artillery monitoring battlefield asset (MAMBA).
It is a mobile phone that quickly monitors C-band radar for the purpose of emy field artillery acquisition and is created for the main task as the main element of a brigade or division level counter battery ssor system. The radar carrier vehicle is a Bandvagn 206 designed and manufactured by Hägglunds, but now it is transported by truck with ISO equipment.
Anti Artillery Radar
The radar is currently developed by Saab AB Electronic Defse Systems (after EMW was sold to Saab in June 2006) and Saab Technologies Norway US.
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ARTHUR detects enemy missiles by looking for what is happening inside the plane. The original ARTHUR A mode could detect guns at 15–20 km and 120 mm artillery at 30–35 km with a range error of perhaps 0.45% of range. This is true for effective counter-battery fire from fat artillery batteries. ARTHUR can operate as an autonomous short-range radar-seeking missile or a long-range missile-seeking system, with two to four radars operating in a configuration. This flexibility allows the system to maintain continuous coverage of the area of interest.
The improved ARTHUR Mod B meets the British Army's MAMBA requirements for finding guns, mortars or rockets. It can detect guns at a range of 20–25 km and 120 mm artillery at 35–40 km with a circular error of 0.35% of the range. MAMBA has been used successfully by British forces in Iraq and Afghanistan, with a 90% success rate.
ARTHUR Mod C has a large antenna and can detect guns at 31 km, missiles at 55 km and rockets at 50–60 km depending on size, and find targets at a rate of 100 per second with a CEP of 0.2% of range for guns and rockets and 0.1% for weapons.
The ARTHUR WLR Mod D will have several mmamt, including an operating range of up to 100 km, a range accuracy of 0.15% and will cover an arc of 120°. The detection range is between 0.8 and 100 km and can be extended up to 200 km. More than 100 targets can be found at a time.
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It can be carried by a C-130 or dropped under a heavy helicopter such as a Chinook. Its air mobility allows it to use fire and quick reaction forces such as air and water units.
The use of ARTHUR in the Nordic Battle Group will count mainly in preventing the use of mines in civilian areas, as the radar can identify mines guilty of killing civilians. It will also be used to alert tactical forces of incoming indirect fire.
Gunners survey a radar site in Al Amarah, Iraq, by the Royal Artillery (RA) 5th Regiment K Battery. Shown in the BV-206 vehicle.
ARTHUR can be used in two main ways: locating weapons and directing fire. Missile tracking is used to determine the location of a gun, missile or rocket and the location of its target. Fire direction is used to adjust self-propelled artillery fire and target formation.
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When an emy missile is detected, the radar constantly monitors the position of the missile, calculates its source and impact and, together with other information, shows it to the radar operator. Depending on the strategy, tactics, strategy, commander's orders and the country's situation, this information can be used to ensure that any troops are in the zone of influence and fire at enemy batteries. If the user has a digital communication network, this message may appear automatically.
ARTHUR can determine whether the projectile is a missile, rocket or missile based on the shape of the trajectory, the speed of the projectile and its range.
Wh and radar shot position calculate the expected impact position of a turbulent shot. These adjustments are calculated and said to be consistent with the target design.
Radars are easy to spot and detect if emy has the requisite ELINT/ESM capabilities. It is likely that these search results will be generated by artillery or aircraft fire (including artillery fire) or ECM. In other cases ground attack through direct fire or small indirect fire is the main threat. The method used against the first is to use over-the-horizon radar to eliminate ground-based detection, reduce transmission time, and use radar groups to move more frequently. Swedish ARTHUR units usually work in three groups to protect the environment. This topic has many issues. Please help fix it or discuss this issue on the talk page. (Learn how and what to remove this template message)
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A counter-battery radar (also known as an anti-missile radar or COBRA) is a radar system that detects the fire of one or more artillery, artillery, or rocket launchers. , and, from their course, locate the position on the ground of the weapon. fired him.
The first battery radar is used in the usual way against weapons, whose advanced parts are very similar and allowed to calculate the location of the manufacturer. Beginning in the 1970s, digital computers with better computational capabilities allowed complex trajectories of long-range missiles to be determined. Typically, these radars will be mounted on fridly missile units or their support units, allowing them to quickly adjust battery fire.
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With the help of modern communication systems, information from a single radar can be spread quickly over long distances. This allows the radar to detect multiple batteries and provide early warning for easy targets.
Modern counter-battery radars can detect counter-batteries up to about 50 kilometers (31 mi; 27 mi) depending on radar power and terrain and weather conditions. Some counter-battery radars can be used to detect mine fires and calculate corrections to set their fires at specific locations, but this is usually a secondary objective.
Radar is a very advanced method of detecting enemy missiles. Indirect fire detection in World War I saw the development of sound, fire detection and aerial reconnaissance, both optical and photographic. Radar, like sound waves and points of light, requires a bad gun, etc., to fire before it can be detected.
The first radar was developed for anti-aircraft purposes shortly before World War II. This was soon followed by fire control radars for ships and coastal mine batteries. The latter can detect spills from missing bullets, with the ability to make adjustments. Gerally, the shell cannot be picked up directly by the radar, because it is small and around to make a difficult return, go quickly for the mechanical antenna next time.
Missile Launcher With Radar Stock Image
Radar operators and anti-aircraft batteries near the front line found they could detect artillery bombs. This is probably helped by the fact that the bomb pack creates a highly reflective corner cube. This emergency agreement led to its use specifically for this task, with a second special trainer if necessary, and the development of a radar designed to detect missiles. Dedicated speed radars are a thing that started in the 1960s and were used until about the 2000s.
Finding the weapon is relatively easy due to its height, fire, and location. Sometimes, immediately after capture and just before impact, the position is almost linear. If the radar observes the projectile in two points immediately after launch, the intermediate signal can be extended to the ground and give the location of the weapon very well, more than enough for the battery gun to hit it quickly. Better radars can also detect high altitudes (higher than 45°C), although such use is rare.
The gun's low-angle approach is often used in more powerful rockets. The low ballistic trajectory is curved, negative for the start of flight but strongly curved towards d. This is enhanced by other small effects such as wind, different air currents and wind effects, which have time to add visible effects in the long light and can be ignored for a short time available as a weapon. This effect is reduced immediately afterwards, but the low angle makes it difficult to see the circle at this time, in contrast to a missile that climbs into the sky almost if instantly. Adding to the problem is the fact that traditional missiles make radar targets difficult.
By the early 1970s, radar systems that could detect weapons seemed possible, and many European and NATO members began.
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