Interference Effects and Interference-Limit Criteria for Radar Receivers

Interference Effects and Interference-Limit Criteria Interference Effects and Interference-Limit Criteria for Radar Receiversfor Radar Receivers

IEEE Electromagnetic Compatibility ConferenceIEEE Electromagnetic Compatibility ConferenceFt. Lauderdale, FL, 26 July 2010Ft. Lauderdale, FL, 26 July 2010

John Carroll, Frank Sanders, Robert SoleJohn Carroll, Frank Sanders, Robert SoleInstitute for Telecommunication Sciences,Institute for Telecommunication Sciences,

NTIA, U.S. Department of Commerce, Boulder, CONTIA, U.S. Department of Commerce, Boulder, COAndAnd

Office of Spectrum ManagementOffice of Spectrum ManagementNTIA, U.S. Department of Commerce, Washington, DCNTIA, U.S. Department of Commerce, Washington, DC

[email protected] (303.497.3367)303.497.3367)[email protected] (303.497.7600) (303.497.7600)

[email protected] (202.482.1245) (202.482.1245)

mailto:[email protected]

mailto:[email protected]

NTIA InvolvementNTIA Involvement

Radar systems have historically been allocated in bands where Radar systems have historically been allocated in bands where they do not share with communication systems. But in recent they do not share with communication systems. But in recent years proposals have been made for communication systems to years proposals have been made for communication systems to operate in radar bands. These include:operate in radar bands. These include:

Satellite Signals;Satellite Signals;

Radio local area networks (RLANS);Radio local area networks (RLANS);

Various new mobile radio systems including WiMax;Various new mobile radio systems including WiMax;

These proposals have raised the question:These proposals have raised the question:At what thresholds do various types of radioAt what thresholds do various types of radiointerference degrade the performance ofinterference degrade the performance ofradar receivers?radar receivers?

Institute for Telecommunication Sciences – Boulder, Colorado


Sharing proposals may directly affect US Government radar systems. Therefore it is critical that technical parameters for sharing between radar receivers and non-radar systems be accurately quantified.

NTIA InvolvementNTIA Involvement

Starting in FY-2002, NTIA Office of Spectrum Management and NTIA Institute for telecommunication Sciences undertook a joint effort to determine thresholds for interference to radar receivers.

PROBLEM: Lack of quantitativedata regarding thresholds at whichvarious types of interferencedegrade performance of radarreceiver systems.

Airport SurveillanceAir-Search Radar


Communication receivers typically experience interference effects as a function of the ratio of the interference level to the level of the desired signal (S/I or C/I).

Radar Interference Criterion: Radar Interference Criterion: I/NI/N

Fixed ground-based weather surveillance radar display in the presence of strong interference.

Radar receivers, in contrast, normally operate against their internally generated noise. They are noise limited and thus the critical interference level parameter is the ratio I/N within the radar receiver IF stage.

But what criteria should be used to determine radar receiver performance at a given I/N level?


OSM and ITS decided to assess radar performance on the basis of probability of detection (Pd) of desired targets as a function of interference level (I/N) in the radar IF stage.

Radar Performance Criterion:Radar Performance Criterion:Probability of Detection of Probability of Detection of

Controlled TargetsControlled Targets

Air surveillance radar ppi display with internally generated targets

Target levels would have to be controlled during measurements. Therefore the targets had to be generated and injected along with interference.

Baseline Pd needed to be marginal: targets strong enough to be easily observed, but nevertheless at the edge of radar’s capability.

Decision was made to set baseline Pd of desired targets at Pd = 90%. Then interference effects would be measured relative to that performance level.


Although procedures have varied slightly from radar to radar, the essential procedure that NTIA (OSM and ITS) has used is:

Radar Interference Measurement Radar Interference Measurement ProcedureProcedure

OSM engineer preparing a maritime radar for signal injection at Curtis Bay Coast Guard Station near Baltimore.

1) Disconnect radar receiver and inject desired (controlled) targets at the RF stage so that they are handled the same way as regular returns.

2) Adjust target level until Pd is as close as possible to 90%.

3) Inject interference signals at the radar RF stage. For each interference modulation, start at I/N=-12 dB, and successively raise the level to:-12 dB, -10 dB, -9 dB, -6 dB, -3 dB, 0 dB, +3 dB, +6 dB, on up to as much as +60 dB if necessary.

Interference types tested include: CW; pulsed CW; CDMA; TDMA; BPSK; OFDM; and UWB; and a variety of simulated radar emissions. Not all modulations have been used on all radars.

4) Count at least 200 desired targets to obtain Pd for each level of interference.


Typical Radar Interference Typical Radar Interference Testing Block DiagramTesting Block Diagram

Note: Some live-target tests have also been performed.


Typical Setup (DoD/FAA/DHS Radar)Typical Setup (DoD/FAA/DHS Radar)


Radars Types Measured (2002-2010)Radars Types Measured (2002-2010)

• Several maritime radars in S and X-bands (in both the US and the UK);

• Airport surface detection radar in X-band;

• Two models of DoD/FAA/DHS long-range radars in L-band;

• Airport surveillance radars in S-band.

• Weather surveillance radars in S and C bands.

• Airborne weather surveillance radar in X-band.

• Precision approach radar in X-band.

• Wind profiler radar in UHF.


Example of Example of PPdd Data Curves Data Curves


Target Losses at Low Target Losses at Low I/NI/N Levels Levels

Target losses at low I/N levels are insidious because there are no ancillary effects to indicate that interference is occurring or that targets are being lost.


Summary of Results to DateSummary of Results to Date

• Interference at high duty cycles (above about 2%), such as from communication signals, typically causes target losses to begin at I/N levels between -10 to -6 dB.;

• Interference at low duty cycles (less than 2%), such as from other radars, can often be sustained at I/N levels as high as +30 dB to +60 dB without degrading receiver performance.

• Target losses due to low levels of interference are insidious because no visible effects are associated with the interference. The targets simply fade away.

• Target losses can occur at any range. Losses do not just occur at the edge of radar coverage, but rather anywhere that the targets are close to radar receiver noise.


Summary of Results to Date Summary of Results to Date (cont.)(cont.)

• Meteorological radars show effects at the lowest levels: Wind profilers show effects at I/N levels as low as -18 dB;

• Interference thresholds go lower as the number of pulses used to integrate radar targets increases.

• Target loss curves (Pd as a function of I/N) are analytically predictable based on the number of pulse echoes used to integrate targets.

• ITU-R criteria of -6 dB I/N threshold for interference analyses are barely adequate for many radar types.


Further Reading:----------------------------------------------- Sanders, Sole, Bedford, Franc, and Pawlowitz:

Effects of Interference on Radar Receivers, (NTIA Technical Report TR-06-444)

Available: http://www.its.bldrdoc.gov/pub/ntia-rpt/06-444/

Documents

Interference Effects and Interference-Limit Criteria for Radar Receivers