초록 ▼

Various embodiments are described herein relating to a radar system and associated methods for detecting targets in the presence of certain types of clutter. The radar system generally comprises hardware operatively configured to obtain first and second sets of radar return signals concurrently, fir

Various embodiments are described herein relating to a radar system and associated methods for detecting targets in the presence of certain types of clutter. The radar system generally comprises hardware operatively configured to obtain first and second sets of radar return signals concurrently, first circuitry operatively configured to detect targets in the first and second sets of radar return signals, and second circuitry operatively configured to identify detected targets due to clutter.

대표청구항 ▼

The invention claimed is: 1. A method of processing radar data, the method comprising: obtaining first and second sets of radar return signals concurrently; detecting targets in the first and second sets of radar return signals; and identifying detected targets due to clutter by: determining the de

The invention claimed is: 1. A method of processing radar data, the method comprising: obtaining first and second sets of radar return signals concurrently; detecting targets in the first and second sets of radar return signals; and identifying detected targets due to clutter by: determining the detected targets common in both the first and second sets of radar return signals; comparing amplitudes associated with the common detected targets to an amplitude threshold; and identifying the common detected targets with amplitudes greater than the amplitude threshold as potential detected targets due to round-based clutter. 2. The method of claim 1, wherein the identifying step further comprises: estimating the height of the potential detected targets; and maintaining the potential detected targets having a height less than a height threshold as potential detected targets due to ground-based clutter. 3. The method of claim 2, wherein the method further comprises setting the height threshold as a function of the range of the potential detected targets based on height estimation accuracy. 4. The method of claim 2, wherein the method further comprises setting the height threshold differently based on different types of ground-based clutter. 5. The method of claim 2, wherein the identifying step further comprises: comparing range and azimuth values of the potential detected targets due to wind turbine clutter with a range gate azimuth map having known locations of wind turbines in the vicinity of the radar system; and maintaining the potential detected targets having range and azimuth values corresponding to a wind farm region as potential detected targets due to wind turbine clutter. 6. The method of claim 1, wherein the method further comprises adjusting detection results by determining it there are any other weaker target detections when the identified targets are due to at least one of wind turbine clutter and bird clutter. 7. The method of claim 1, wherein the method further comprises repeating detection to determine other detected targets while taking into account the effect of the detection results of the identified targets due to wind turbine clutter by discarding a strongest detection result and selecting a second strongest detection result as a possible target detection. 8. The method of claim 1, wherein detecting targets in a given set of radar return signals for a range cell comprises: pre-processing the given set of radar return signals; performing Doppler processing on the pre-processed given set of radar return signals to produce several Doppler outputs; performing CFAR detection on the several Doppler outputs to produce several CFAR detection results; and merging the CFAR detection results to obtain detection results for the range cell. 9. The method of claim 8, wherein the method further comprises applying binary integration to the merged CFAR detection results for several consecutive scans. 10. The method of claim 8, wherein the method further comprises generating a CFAR threshold for performing the CFAR detection for a given Doppler output by: averaging values in an early range window prior to the range cell to obtain a first average; averaging values in a late range window after the range cell to obtain a second average; selecting the smaller of the first and second averages to produce an initial value; determining a clutter level in a clutter map that corresponds to the range cell and the given Doppler output; setting the CFAR threshold to the larger of the initial value and the clutter level; and adding a constant based on a desired false alarm rate to the CFAR threshold. 11. A computer readable medium for use in processing radar data, the computer readable medium having stored thereon program code executable by a processor, the program code for implementing a method comprising: concurrently obtaining first and second sets of radar return signals; concurrently processing the radar return signals in high and low beam reception channels by beamforming receive beams to high and low directions to detect targets in the first and second sets of radar return signals; and identifying detected targets due to clutter by: determining the detected targets common in both the first and second sets of radar return signals; estimating the height of the common detected targets; and identifying the common detected targets having heights less than a height threshold. 12. A radar system comprising: hardware operatively configured to obtain first and second sets of radar return signals concurrently; first circuitry operatively configured to detect targets in the first and second sets of radar return signals; and second circuitry operatively configured to identify detected targets due to clutter by determining the detected targets common in both the first and second sets of radar return signals, comparing amplitudes associated with the common detected targets to an amplitude threshold and identifying the common detected targets with amplitudes greater than the amplitude threshold as potential detected targets due to around-based clutter. 13. The system of claim 12, wherein the second circuitry is operatively configured to estimate the height of the potential detected targets and maintain the potential detected targets having a height less than a height threshold as potential detected targets due to ground-based clutter. 14. The system of claim 13, wherein the height threshold is a function of the range of the potential detected targets based on height estimation accuracy. 15. The system of claim 13, wherein the height threshold is set differently based on different types of ground-based clutter. 16. The system of claim 13, wherein the second circuitry is operative configured to compare range and azimuth values of the potential detected targets due to wind turbine clutter with a range gate azimuth map having known locations of wind turbines in the vicinity of the radar system, and maintain the potential detected targets having range and azimuth values corresponding to a wind farm region as potential detected targets due to wind turbine clutter. 17. The system of claim 12, wherein the first and second circuitry are operatively configured to adjust detection results by determining if there are any other weaker target detections when the identified targets are due to at least one of wind turbine clutter or bird clutter. 18. The system of claim 12, wherein the first circuitry is operatively configured to repeat detection to determine other detected targets while taking into account the effect of the detection results of the identified targets due to wind turbine clutter by discarding a strongest detection result and selecting a second strongest detection result as a possible target detection. 19. The system of claim 12, wherein the first circuitry comprises a signal processing chain configured to detect targets in a given set of radar return signals, wherein the signal processing chain comprises: a beam receiver operatively configured to pre-process the given set of radar return signals; a Doppler filter bank operatively configured to perform Doppler processing on the pre-processed given set of radar return signals to produce several Doppler outputs; a CFAR detection module operatively configured to perform CFAR detection on the several Doppler outputs to produce several CFAR detection results; and a CFAR merge module operatively configured to merge the CFAR detection results to obtain detection results for the range cell. 20. A computer readable medium for use in processing radar data, the computer readable medium having stored thereon program code executable by a processor, the program code for implementing a method comprising: concurrently obtaining first and second sets of radar return signals; concurrently processing the radar return signals in high and low beam reception channels by beamforming receive beams to high and low directions to detect targets in the first and second sets of radar return signals; and identifying detected targets due to clutter by: determining the detected targets common in both the first and second sets of radar return signals; comparing amplitudes associated with the common detected targets to an amplitude threshold; and identifying the common detected targets with amplitudes greater than the amplitude threshold as potential targets due to ground-based clutter. 21. A method of processing radar data, the method comprising: obtaining first and second sets of radar return signals concurrently; detecting targets in the first and second sets of radar return signals; and identifying detected targets due to clutter by: determining the detected targets common in both the first and second sets of radar return signals; estimating the height of the common detected targets; and identifying the common detected targets having heights less than a height threshold as potential detected targets due to at least one of wind turbine clutter and bird clutter. 22. The method of claim 21, wherein the method further comprises setting the height threshold as a function of the range of the potential detected targets based on height estimation accuracy. 23. The method of claim 21, wherein the method further comprises setting the height threshold differently based different types of ground-based clutter. 24. The method of claim 21, wherein the identifying step further comprises: comparing range and azimuth values of the potential detected targets due to wind turbine clutter with a range gate azimuth map having known locations of wind turbines in the vicinity of the radar system; and maintaining the potential detected targets having range and azimuth values corresponding to a wind farm region as potential detected targets due to wind turbine clutter. 25. A radar system comprising: hardware operatively configured to obtain first and second sets of radar return signals concurrently; first circuitry operatively configured to detect targets in the first and second sets of radar return signals; and second circuitry operatively configured to identify detected targets due to clutter by determining the detected targets common in both the first and second sets of radar return signals, estimating the height of the common detected targets, and identifying the common detected targets having heights less than a height threshold as potential detected targets due to ground-based clutter. 26. The system of claim 25, wherein the height threshold is a function of the range of the potential detected targets based on height estimation accuracy. 27. The system of claim 25, wherein the height threshold is set differently based on wind turbine clutter and bird clutter. 28. The system of claim 25, wherein the second circuitry is operatively configured to compare range and azimuth values of the potential detected targets due to wind turbine clutter with a range gate azimuth map having known locations of wind turbines in the vicinity of the radar system, and maintain the potential detected targets having range and azimuth values corresponding to a wind farm region as potential detected targets due to wind turbine clutter.