Missile approach warning system

The cylindrical pod pointing backwards, just above the engines, is the missile approach warning receiver (part of Praetorian DASS)

A missile approach warning system (MAW) is part of the avionics package on some military aircraft. A sensor detects attacking missiles. Its automatic warning cues the pilot to make a defensive maneuver and deploy the available countermeasures to disrupt missile tracking.

Guided surface-to-air missile (SAM) systems were developed during World War II and began to make their presence felt in the 1950s. In response, electronic countermeasures (ECM) and flying tactics were developed to overcome them. They proved to be quite successful provided that a reliable and timely threat warning was given.

The infrared-seeking missile threat

Analysis of aircraft losses due to enemy action since the 1960s shows that at least 70% of all losses were attributed to passive heat seeking i.e. Infrared (IR) guided missiles^{[citation needed]}. This might be surprising given that radar guided SAM systems have longer engagement ranges, are faster, have higher maneuvering potential, carry larger warheads and are equipped with proximity fuzes.

The main reason why IR guided missiles were so effective was that it took much longer to develop effective warning systems against them. Most aircraft that were shot down never knew that the missiles were coming. Radar warning receivers on the other hand already proved their effectiveness by the early 1970s which considerably improved the survival rate of aircraft against radar threats.

The first air-to-air IR missiles appeared in the 1950s. The technology allowed more compact missile designs and made it possible to develop IR man-portable air-defense systems (MANPADS) i.e. shoulder-launched missiles, which became operational by the 1960s.

IR MANPADS are relatively cheap, quite robust, easy to operate and difficult to detect. They also do not require the infrastructure often associated with radar-guided SAM deployments, which often reveals their presence.

Vast quantities of MANPADS have been manufactured (as many as 700,000 produced since 1970^[1]). Large numbers proliferated during the Cold War and immediate post Cold War era. Substantial quantities are available and affordable on the black market and have found their way into the hands of "non state" organizations or the so-called "asymmetric" threat. (An estimate by Jane's Intelligence Review of Feb 2003 puts this number as high as 150 000^[2]). An article "Proliferation of MANPADS and the Threat to Civil Aviation" of August 13, 2003 by Jane's Terrorism and Insurgency Centre estimates that the black market price of MANPADS like the SA-7 could be as low as $5,000.^[3]

Intelligence regarding the whereabouts of MANPADS, especially in the hands of "non state" organizations, is usually vague and unreliable. This, in turn, makes it difficult to anticipate where and when to expect MANPADS attacks.

The 2nd- and 3rd-generation MANPADS appeared by the 1980s and further increased the performance and effectiveness of MANPADS due to advanced new seeker head technology, improved rocket motors, and aerodynamic refinements. Their performance improved in terms of lethal range, minimum launch angle, maneuvering potential and all aspect engagement angles (1st-generation MANPADS were restricted to only rear sector attacks). They also became more ECM resistant.

MANPADS therefore became even more lethal specifically against more vulnerable platforms such as helicopters, light aircraft, and commercial and military transport aircraft (during approaches and departures). The slower speed of these platforms forces them to spend more time within the kill zones of MANPADS compared to high performance fighter and strike aircraft.

At least 35 MANPADS attacks on civilian aircraft are on record. Twenty-four were shot down killing about 500 people in the process.

Missile approach warning (MAW) system requirements

Protecting aircraft against IR guided missiles depends in most cases firstly on reliable detection and warning of missiles and secondly on applying effective ECM.

An exception to this are omni-directional IR jammers which do not make use of missile warning at all, as they simply radiate modulated IR energy for as long as they are switched on. These jammers have been around since the 1970s and when the correct jamming modulation techniques were applied, were reasonably effective against 1st-generation amplitude-modulated MANPADS, which operated in the near-IR band (1 to 2 micrometres (μm)). The arrival of 2nd- and 3rd-generation MANPADS changed that. They operate in the mid-IR band (3 to 5 μm) and use more advanced modulation techniques (for example frequency modulation). Instead of jamming these missiles, the omni-directional IR jammer became a source for the missiles to home in.

Functional requirements

Providing timely warning against IR MANPADS is a challenge. They give no warning of their presence prior to launch, they do not rely on active IR, radar guidance or a laser designator, which would possibly emit a detectable radiation. They are typically fire-and-forget and can lock on and engage a target, speed to the target and destroy it in seconds. They have a small but visible radar signature and also a propellant which burns – depending on the platform, typically for a very short duration.

MANPADS are relatively short-range weapons, typically up to about five kilometers with the heart of the kill envelope one to three kilometers. They therefore allow very little margin for error to effectively counter them as the time to impact (TTI) on a target at one kilometer, is only about three seconds. The TTI for targets at three and five kilometers is also relatively short – only seven to a little over eleven seconds respectively.

The MAW must provide reliable and timely warning to allow appropriate counter measure responses. Near 100% probability of warning (POW) and very fast reaction times to counter nearby missile launches (in the order of one second) are essential.

Air crew will rely on the system only if they have high confidence in it. The MAW must also have sufficiently low false alarm rates (FAR), even when illuminated by multiple sources (which may include threats) from different directions.

Quick response times and low FAR are inherently conflicting requirements. An acceptable solution requires a balanced approach to provide the most successful end result without compromising the POW. Since a longer time-to-impact (TTI) warning is almost invariably desirable, this leads to the conclusion that there is something like a too-low FAR: all warning systems gather data, and then make decisions when some confidence level is reached. False alarms represent decision errors, which (assuming optimal processing) can be reduced only by gathering more information, which means taking more time, inevitably resulting in a reduced time-to-impact. Most users would tolerate an increased FAR (up to some point where it starts limiting operations) instead of a reduced TTI, because their probability of survival depends fairly directly on the TTI, which represents the time in which countermeasures can be deployed.

Accurate azimuth and elevation angle of attack (AOA) information can be another very important requirement. Directional IR counter measures (DIRCM) systems depend on MAW systems for accurate enough initial pointing (about two degrees) to ensure that the DIRCM acquires and engages incoming missiles timely and successfully.

Accurate AOA is also important in deciding the dispensing direction of the counter measure decoys (flares). It is vital to avoid the situation where the platform and the dispensed decoys both remain within the instantaneous field of view (IFoV) of incoming missiles. In situations like that missiles could very well, once they pass the decoys, still hit the platform. This is of particular importance where separation between the decoys and the platform takes too long as is the case with slow flying aircraft.

Accurate AOA is further important where the platform should preferably maneuver when dispensing decoys to increase the miss distance. This is more applicable to fast jets where their high speed tends to negate the separation caused by the decoy's ejection velocity. A turn towards approaching missiles to establish/increase the angle between the decoy and the platform is especially important in cases where a missile approaches from the rear between the five or seven 'o clock sectors. If the AOA is not accurate enough, the pilot could very well turn in the wrong direction and set himself up for the situation as described above.

The system must also be fully automated as the human reaction time in relevant cases (short range launches) is too long.

Physical requirements

Light aircraft, helicopters, and fighters usually have limited space and mass capacity for additional equipment. The system may also cause adverse aerodynamic drag which demands minimal physical size and number of boxes. The power consumption must further be kept within the capacity of the platform's electrical system.

Human-machine interface (HMI) requirements

Integrated display and control functions are desirable to avoid duplication on instrument panels where space is limited. If a platform is equipped with both radar and missile warning systems, the HMI should display both threats clearly and unambiguously.

The integrated HMI must also indicate the system's operating status, serviceability status, mode of operation, remaining decoy quantities etc. Separate control panels are justified only for safety of flight purposes such as ECM on/off and decoy jettison functions.

Cost considerations

Procuring electronic warfare (EW) self-protection systems has direct and indirect cost implications.

Direct costs involve the initial price of the system, spare parts as well as test equipment to ensure that the performance and availability of the systems is maintained throughout their entire life cycle.

Installing and integrating EW systems on aircraft is another direct cost

Indirect cost on the other hand involves degradation of the aircraft's performance as a result of having the system on-board which in turn impacts negatively on the operating cost of the aircraft.

The lowest initial price of a system does therefore not necessarily offer the best solution as all the factors needs to be considered. The overall cost effectiveness of systems i.e. price versus performance is more important in deciding which system to select.

Types of MAW systems

Three different technologies have been used for MAW systems, i.e. systems based on: Pulse-Doppler radar, Infrared, and Ultraviolet. Each technology has its advantages and disadvantages which can be summarized as follows:

Pulse-Doppler–based MAW

See also: Pulse-Doppler radar

Advantages

• Can measure distance and speed of approaching missiles. It can therefore determine the time to impact (TTI) and optimize the timing of countermeasure (flare) dispensing.
• Does not depend on the propulsion unit of missiles to be burning.
• Less sensitive to weather conditions.

Disadvantages

• In sophisticated threat environments, active systems could reveal the aircraft's presence with the radar radiation by the MAW and therefore increase its vulnerability.
• Detection range of small missiles with low radar cross section like MANPADS is limited and could result in marginal warning time and consequent late decoy dispensing.
• Cannot measure direction accurately enough to direct DIRCM systems.
• Susceptible to false alarms caused by other RF sources.
• Can cause interference with ground air traffic control radars if operating frequency is not selected carefully.
• More difficult to integrate than passive systems due to spatial limitations.

Infrared-based MAW

See also: Infrared and Thermographic camera

Advantages

• In good weather conditions, the atmospheric transmission of IR radiation tends to be better than that of solar-blind UV radiation.
• Can potentially achieve longer detection ranges at altitude where there is no ground clutter.
• Can potentially detect the kinetic heat of missiles after motor burnout at altitude, but probably not at low level due to high IR background clutter.
• Provides good AOA information for pointing a DIRCM and good decision making regarding decoy dispensing direction and maneuvering.

Disadvantages

• Very low IR transmission through liquid water and ice, which precludes all-weather operation. Even a few tens of micrometers of water on the lens, or in the atmosphere between the threat and the sensor, is sufficient to effectively blind both MWIR and LWIR sensors.
• Must compete with massive amounts of natural (sun) and man-made IR clutter.
• False alarm rate and/or probability of warning is therefore a huge problem against surface-to-air missiles due to high IR background clutter originating from the earth.
• Needs vast computing power to alleviate false alarm problem which in turn drives up cost.
• Two colour detectors are used in some systems to assist in the suppression of background clutter and lower FAR. Even though it solves some problems, it creates others as it complicates the system further due to the optical, sensitivity and extremely high pixel rate requirements which impact negatively on cost and reliability.
• Cannot provide actual range information.
• Traditionally IR detectors have very narrow instantaneous fields of view to achieve good enough signal to target ratio. Large detector arrays are therefore required to provide 360° azimuth coverage which is another cost driver.
• Requires cooled detectors which complicates life cycle logistic support and result in high cost of ownership.
• Detection range could be limited against future new technology low IR/UV emission rocket motors.

Ultraviolet-based MWS

See also: Ultraviolet

Advantages

• Operates in solar blind UV spectral wavelength region and therefore has no natural (sun) false alarms. UV based MAW systems therefore have a much reduced false alarm problem to solve compared to IR based systems.
• Very good probability of warning in high clutter background environments.
• All-weather operation, as it is impervious to solar clutter, and hardly affected by liquid water.
• Wide instantaneous field of view.
• Provide very good AOA information for good decoy dispensing decision making, maneuvering and for pointing DIRCMs.
• Has fast response time against nearby missile launches.
• Is a simpler system than pulse Doppler & IR technologies.
• Does not require cooling and needs only moderate computing power.
• Low life cycle cost.

Disadvantages

• To detect approaching missiles, the rocket motor of the missile must be burning – it requires the high effective burning temperatures associated with solid fuel rocket motors.
• IR-based systems are probably better at altitude but UV is better against surface-to-air missiles.
• Cannot provide actual range information but can derive TTI from the rapid increase in amplitude of the approaching missile's signal.
• Detection range could be limited against future new technology low IR/UV emission rocket motors.

Implementations of MAW systems

Current available MAW systems as well as those under development, represent all three types of technologies. Each technology has strong and weak points and none provide a perfect solution.

Pulse-Doppler radar-based

See also: Pulse-Doppler radar

France

• MWS - 20 (Damien) originally from Dassault Electronique (now Thales)

Israel

• EL/M-2160 (ALQ – 199) from ELTA

Japan

• J/APQ – 1 * from Mitsubishi Electronic Corporation

Russia

• LIP MAW (obsolete system)
• Arbalet-D from Phazatron NIIR Corporation

UK

• PVS 2000 originally from GEC Marconi and Plessey Avionics (now SELEX and Thales) (obsolete system)^[4]

UK and Italy

• AMIDS from SELEX and Elettronica (component of praetorian DASS, developed from PVS 2000)^[5]

US

• AN/ALQ – 127 originally from Westinghouse (now Northrop Grumman) (obsolete system)
• AN/ALQ – 153 originally from Westinghouse (now Northrop Grumman) (obsolete system)
• AN/ALQ – 154 from AIL (obsolete system)
• AN/ALQ – 156 from BAE Systems EI&S

Infrared-based

Israel

• PAWS from Elisra

France

• DDM-SAMIR/DDM-NG from Sagem and MBDA^[6]

Germany

• PIMAWS from BGT (uncertain of production/development status)

Italy

• Leonardo MAIR^[7]

Germany and France

• MIRAS from Hensoldt (Hensoldt Holding GmbH), Thales and Airbus DS GmbH

Russia

• President-S (BKO) from KRET and Scientific-Research Institute Ekran^[8]

UK

• ELIX-IR from Thales UK (uncertain of production/development status)

US

• AN/AAR 44B from L-3 Cincinnati Electronics
• MIMS from Northop Grumman (uncertain of production/development status)
• JATAS, under development by Alliant Techsystems (ATK) and BAE Systems under a USN contract, with initial operational deployment scheduled for late 2015
• AN/AAR-56 from Lockheed Martin for F-22 (operational)
• AN/AAQ-37 distributed aperture system (DAS) from Northrop Grumman for F-35 (In production/testing)

US and Israel

• PAWS - 2 from Raytheon and Elisra

India

• DCMAWS from DARE (lab of DRDO).^[9][10][11]

Ultraviolet-based

Germany

• AN/AAR 60 or MILDS (Missile Launch Detection System) from Hensoldt Holding GmbH.^[12]

Israel

• Guitar – 350 from Rafael (Uncertain of production/development status)

Sweden/South Africa

• MAW 300 from Saab Avitronics^[13]

US

• AN/AAR 47 with upgraded AN/AAR-47A(V)2 sensors.
• AN/AAR 54 originally from Westinghouse (now Northrop Grumman)
• AN/AAR 57 originally from Sanders (now BAE Systems EI&S)^[14]

Russia

• 101KS-U part of the 101KS Atoll electro-optical (EO) system for the Russian Air Force Su-57 fifth generation aircraft.

India

• UVMAWS from DRDO^[15]

See also

• Sukhoi Su-30MKM MAW-300
• Radar warning receiver
• Infrared homing (passive missile guidance system)
• Directional infrared counter measures
• Electronic counter-countermeasures
• Active radar homing

References

1. Transnational Threats Update, vol. 1, 2003
2. http://www.janes.com/extract/jir2003/jir00523.html. Retrieved 31 January 2022. {{cite web}}: Missing or empty |title= (help)
3. "Proliferation of MANPADS and the threat to civil aviation". California Aviation Alliance. 13 August 2003. Archived from the original on 24 July 2018. Retrieved 31 January 2022.
4. "Missile Approach Warner and Advanced Missile Detection System, PVS2000 :: Rochester Avionic Archives". rochesteravionicarchives.co.uk. Retrieved 2023-05-01.
5. "Missile Approach Warner" (PDF). Rochester Avionics Archives. 1993. Retrieved 2024-03-27.
6. "Le premier Rafale de la "tranche 4" débarque dans les forces". Air et Cosmos. 23 September 2013. Retrieved 2020-08-04.
7. "MAIR". Leonardo. Retrieved 7 April 2023.
8. "Ancile".
9. "Dual Colour Missile Approach Warning System (DCMAWS) for Fighter Aircraft | Defence Research and Development Organisation - DRDO, Ministry of Defence, Government of India". www.drdo.gov.in. Retrieved 2023-08-06.
10. www.ETGovernment.com. "DRDO to showcase technologies, innovations and capabilities at Aero India 2021 - ET Government". ETGovernment.com. Retrieved 2023-08-06.
11. "CAG flags DRDO declaring 20 mission mode projects 'successful' despite not achieving objectives". www.thehindubusinessline.com. 2022-12-22. Retrieved 2023-08-06.
12. "MILDS AN/AAR-60 Missile Warning System." EADS North America, Retrieved 18 July 2013.
13. "MAW 300^{[permanent dead link]}" Saab Avitronics
14. "Northrop Grumman to Install AN/AAR-54(V) Warning Systems on Royal Netherlands Helicopters". Northrop Grumman Newsroom. 16 June 2001. Archived from the original on 3 July 2022. Retrieved 3 July 2022.
15. "DRDO-built radar tech to power IAF's Airbus aircraft". The Times of India. 2021-11-26. ISSN 0971-8257. Retrieved 2023-08-06.

External links

• Aircraft Self Protection (PDF)
• Heat-Seeking Missile Guidance