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(near Neubrandenburg in Mecklenburg/Western Pommerania)

Secondary Surveillance Radar (SSR) is a radar system used in air traffic control (ATC), which not only detects and measures the position of aircraft but also requests additional information from the aircraft itself such as its identity and altitude. Unlike primary radar systems, which measure only the range and bearing of targets by detecting reflected radio signals, rather like seeing an object in a beam of light, SSR relies on its targets being equipped with a radar transponder (aviation), which replies to each interrogation signal by transmitting its own response containing encoded data. SSR is based on the military Identification Friend or Foe (IFF) technology originally developed during the second world war, and the two systems are still compatible today.

Overview The rapid wartime development of radar had obvious applications for air traffic control (ATC) as a means of providing continuous surveillance of air traffic disposition. Precise knowledge of the positions of aircraft would permit a reduction in the normal procedural separation standards, which in turn promised considerable increases in the efficiency of the airways system. This type of radar (now called a 'primary' radar) can detect and report the position of anything that reflects its transmitted radio signals including, depending on its design, aircraft, birds, weather and land features. For air traffic control purposes this is both an advantage and a disadvantage. Its targets do not have to co-operate, they only have to be within its coverage and be able to reflect radio waves, but it only indicates the position of the targets, it does not identify them. When primary radar was the only type of radar available, the correlation of individual radar returns with specific aircraft typically was achieved by the Controller observing a directed turn by the aircraft.

The need to be able to identify aircraft more easily and reliably led to another wartime radar development, the Identification Friend or Foe (IFF) system, which had been created as a means of positively identifying friendly aircraft from enemy. This system, which became known in civil use as Secondary Surveillance Radar (SSR) or in the USA as the Air Traffic Control Radar Beacon System (ATCRBS), relies on a piece of equipment aboard the aircraft known as a 'transponder'. The transponder is a radio receiver and transmitter which receives on one frequency (1030 MHz) and transmits on another (1090 MHz). The target aircraft's transponder replies to signals from an interrogator (usually, but not necessarily, a ground station co-located with a primary radar) by transmitting a coded reply signal containing the requested information.

Both the civilian SSR and the military IFF have become much more complex than their war-time ancestors, but remain compatible with each other, not least to allow military aircraft to operate in civil airspace. SSR can now provide much more detailed information and it also permits the exchange of data directly between aircraft for collision avoidance. Given its primary military role of reliably identifying friends, IFF has much more secure (encrypted) messages to prevent 'spoofing' by the enemy, and also is used on all kinds of military platforms including air, sea and land vehicles.

Operation The purpose of this system is to improve the ability to detect and identify aircraft while it additionally provides automatically the Flight Level (pressure altitude) of a flight. An SSR continuously transmits interrogation pulses (selectively rather than continuously in Mode-4, Mode-5, and Mode-S) as its antenna rotates, or is electronically scanned in space. A transponder on an aircraft that is within line-of-sight range 'listens' for the SSR interrogation signal and sends back a reply that provides aircraft information. The reply sent depends on the mode that was interrogated (see below). The aircraft is then displayed as a tagged icon on the controller's radar screen at the calculated bearing and range. An aircraft without an operating transponder still may be observed by primary radar, but would be displayed to the controller without the benefit of SSR derived data.

A cross-band beacon is used, which simply means that the interrogation pulses are at one frequency (1030 MHz) and the reply pulses are at a different frequency (1090 MHz).

Modes There are several transponder modes, each offering different information

For civilian flights according to ICAO the modes of operations are the A, C and S

The A mode is based on a 4-digit code using numbers between 0 and 7 assigned by the Air traffic control and set by the pilot enabling identification and monitoring. Mode C transmits pressure altitude, read automatically from the aircraft altimeter. The mode S is triggered by a mode-S interrogation and can provide the particular information that is requested by the interrogation signal. For modes A and C, all aircraft receiving the interrogation signal will reply, whereas mode S allows aircraft to be addressed individually. In modern Air traffic control systems the data appear with alphanumeric characters in a tag or label linked to the flight position symbol on the radar screen.

Future uses Weapon scientists and science fiction authors have both envisaged similar systems for general use on the battlefield — identifying vehicles, installations or even individual soldiers. Apart from the difficulty of providing reliable systems of sufficiently compact size and low weight, there are also concerns that the use of these devices may reduce concealment from enemy fire — unlike in aerial combat, where the mere presence of enemy units is usually well known.

See also

External links



(near Neubrandenburg in Mecklenburg/Western Pommerania)

Secondary Surveillance Radar (SSR) is a radar system used in air traffic control (ATC), which not only detects and measures the position of aircraft but also requests additional information from the aircraft itself such as its identity and altitude. Unlike primary radar systems, which measure only the range and bearing of targets by detecting reflected radio signals, rather like seeing an object in a beam of light, SSR relies on its targets being equipped with a radar transponder (aviation), which replies to each interrogation signal by transmitting its own response containing encoded data. SSR is based on the military Identification Friend or Foe (IFF) technology originally developed during the second world war, and the two systems are still compatible today.

Overview The rapid wartime development of radar had obvious applications for air traffic control (ATC) as a means of providing continuous surveillance of air traffic disposition. Precise knowledge of the positions of aircraft would permit a reduction in the normal procedural separation standards, which in turn promised considerable increases in the efficiency of the airways system. This type of radar (now called a 'primary' radar) can detect and report the position of anything that reflects its transmitted radio signals including, depending on its design, aircraft, birds, weather and land features. For air traffic control purposes this is both an advantage and a disadvantage. Its targets do not have to co-operate, they only have to be within its coverage and be able to reflect radio waves, but it only indicates the position of the targets, it does not identify them. When primary radar was the only type of radar available, the correlation of individual radar returns with specific aircraft typically was achieved by the Controller observing a directed turn by the aircraft.

The need to be able to identify aircraft more easily and reliably led to another wartime radar development, the Identification Friend or Foe (IFF) system, which had been created as a means of positively identifying friendly aircraft from enemy. This system, which became known in civil use as Secondary Surveillance Radar (SSR) or in the USA as the Air Traffic Control Radar Beacon System (ATCRBS), relies on a piece of equipment aboard the aircraft known as a 'transponder'. The transponder is a radio receiver and transmitter which receives on one frequency (1030 MHz) and transmits on another (1090 MHz). The target aircraft's transponder replies to signals from an interrogator (usually, but not necessarily, a ground station co-located with a primary radar) by transmitting a coded reply signal containing the requested information.

Both the civilian SSR and the military IFF have become much more complex than their war-time ancestors, but remain compatible with each other, not least to allow military aircraft to operate in civil airspace. SSR can now provide much more detailed information and it also permits the exchange of data directly between aircraft for collision avoidance. Given its primary military role of reliably identifying friends, IFF has much more secure (encrypted) messages to prevent 'spoofing' by the enemy, and also is used on all kinds of military platforms including air, sea and land vehicles.

Operation The purpose of this system is to improve the ability to detect and identify aircraft while it additionally provides automatically the Flight Level (pressure altitude) of a flight. An SSR continuously transmits interrogation pulses (selectively rather than continuously in Mode-4, Mode-5, and Mode-S) as its antenna rotates, or is electronically scanned in space. A transponder on an aircraft that is within line-of-sight range 'listens' for the SSR interrogation signal and sends back a reply that provides aircraft information. The reply sent depends on the mode that was interrogated (see below). The aircraft is then displayed as a tagged icon on the controller's radar screen at the calculated bearing and range. An aircraft without an operating transponder still may be observed by primary radar, but would be displayed to the controller without the benefit of SSR derived data.

A cross-band beacon is used, which simply means that the interrogation pulses are at one frequency (1030 MHz) and the reply pulses are at a different frequency (1090 MHz).

Modes There are several transponder modes, each offering different information

For civilian flights according to ICAO the modes of operations are the A, C and S

The A mode is based on a 4-digit code using numbers between 0 and 7 assigned by the Air traffic control and set by the pilot enabling identification and monitoring. Mode C transmits pressure altitude, read automatically from the aircraft altimeter. The mode S is triggered by a mode-S interrogation and can provide the particular information that is requested by the interrogation signal. For modes A and C, all aircraft receiving the interrogation signal will reply, whereas mode S allows aircraft to be addressed individually. In modern Air traffic control systems the data appear with alphanumeric characters in a tag or label linked to the flight position symbol on the radar screen.

Future uses Weapon scientists and science fiction authors have both envisaged similar systems for general use on the battlefield — identifying vehicles, installations or even individual soldiers. Apart from the difficulty of providing reliable systems of sufficiently compact size and low weight, there are also concerns that the use of these devices may reduce concealment from enemy fire — unlike in aerial combat, where the mere presence of enemy units is usually well known.

See also

External links



Amazon.co.uk: Secondary Surveillance Radar (Artech House Radar Library ...
Amazon.co.uk: Secondary Surveillance Radar (Artech House Radar Library): Michael C. Stevens: Books ...

Secondary surveillance radar - Wikipedia, the free encyclopedia
Secondary Surveillance Radar (SSR) is a radar system used in air traffic control (ATC), which not only detects and measures the position of aircraft but also requests additional ...

Identification friend or foe - Wikipedia, the free encyclopedia
Challenge-response authentication; Transponder; Squawk code; Secondary surveillance radar; Automatic Target Recognition [edit] References. U.S. Federal Standard 1037C; U.S. Department of Defense ...

BBC - h2g2 - Primary and Secondary Radar - A588684
Add your Opinion! There are tens of thousands of h2g2 Guide Entries, written by our Researchers. If you want to be able to add your own opinions to the Guide, simply become a ...

Identify Friend or Foe/Secondary Surveillance Radar (IFF/SSR ...
The Civil Aviation Authority’s Directorate of Airspace Policy (DAP) provides the focal point and Secretariat to the Cabinet Office sponsored National IFF/SSR Committee (NISC ...

Identification Friend or Foe / Secondary Surveillance Radar (IFF/SSR ...
IFF/SSR Home Page ... Identification Friend or Foe/Secondary Surveillance Radar (IFF/SSR) The Civil Aviation Authority’s Directorate of Airspace Policy (DAP) provides the focal ...

Secondary Surveillance Radar (SSR)
Companies supplying Secondary Surveillance Radar (SSR)

Intelcan achieves the successful implementation of Eldis Canada ...
Intel installs new monopulse secondary surveillance radar technology in Azerbaijan ... Intelcan achieves the successful implementation of Eldis Canada Monopulse Secondary ...

Intelcan's Monopulse Secondary Surveillance Radar (MSSR) - Intelcan ...
Intelcan-manufactured Monopulse Secondary Surveillance Radar (MSSR). ... Intelcan - ACC and ATC Centres, Surveillance, Navigation, Voice and Data Communications for Today's and ...

Amazon.com: Secondary Surveillance Radar (Artech House Radar Library ...
Amazon.com: Secondary Surveillance Radar (Artech House Radar Library): Michael Stevens: Books ... Hardcover: 316 pages; Publisher: Artech House Publishers (March 1, 1988) Language ...

 

Secondary Surveillance Radar



 
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