초록 ▼

Methods and systems for suppressing clutter, for example, ground clutter, in radar systems are provided. The methods and systems can be employed in radar systems having an antenna system and at least two receive beams, for example, a main beam and an auxiliary beam. The methods include receiving dat

Methods and systems for suppressing clutter, for example, ground clutter, in radar systems are provided. The methods and systems can be employed in radar systems having an antenna system and at least two receive beams, for example, a main beam and an auxiliary beam. The methods include receiving data streams from each of the at least two receive beams, where each data stream is associated with range bins and include data representing clutter, and, before or after Doppler filtering, generating an adaptive weight from summations of the data streams for each of the range bins, and applying the generated weight to at least one of the data streams to provide Doppler filtered and spatially nulled data streams that can be used to more accurately identify targets, such as, aircraft.

대표청구항 ▼

1. A method for suppressing clutter when detecting targets of interest with a radar system comprising an antenna system and at least two receive beams, the method comprising: receiving I/Q data streams from each of the at least two receive beams, each of the I/Q data streams associated with range bi

1. A method for suppressing clutter when detecting targets of interest with a radar system comprising an antenna system and at least two receive beams, the method comprising: receiving I/Q data streams from each of the at least two receive beams, each of the I/Q data streams associated with range bins and including data representing clutter;Doppler filtering the I/Q data streams at each of the range bins and thereby generating for each of the I/Q data streams multiple Doppler-filtered I/Q data streams for each of the range bins;generating a weight from summations of the I/Q data streams for each of the range bins;applying the generated weight to at least one of the multiple Doppler-filtered I/Q data streams to provide at least one weighted I/Q data stream;combining the at least one weighted I/Q data stream with one of the other multiple Doppler-filtered I/Q data streams to thereby generate at least one weighted Doppler-filtered I/Q data stream representing spatial nulling of clutter for each of the range bins; andusing the at least one weighted Doppler-filtered I/Q data stream representing spatial nulling of clutter for each of the range bins to detect targets. 2. The method as recited in claim 1, wherein generating the weight comprises computing the weight based on a summation of the I/Q data streams across pulses for each of the I/Q data streams. 3. The method as recited in claim 1, wherein the at least two receive beams comprise at least a main beam and an auxiliary beam. 4. The method as recited in claim 1, wherein the method further comprises comparing at least one of the summations of the I/Q data streams to a predetermined threshold. 5. The method as recited in claim 4, wherein, when the at least one of the summations exceeds the predetermined threshold, equating the weight to zero. 6. The method as recited in claim 1, wherein the method further comprises comparing an absolute value of the weight to a predetermined threshold. 7. The method as recited in claim 6, wherein generating the weight from the summations of the I/Q data streams comprises generating the weight from a quotient including the summations of the I/Q data streams, and wherein, when the absolute value of the quotient exceeds the predetermined threshold weight, decreasing the quotient. 8. The method as recited in claim 6, wherein generating the weight from the summations of the I/Q data streams comprises equating the weight to a quotient of one of the summations of the I/Q data streams divided by a sum of another of the summations of the I/Q data streams and a predetermined constant, and wherein comparing the absolute value of the weight to the predetermined threshold comprises comparing the absolute value of the quotient to the predetermined threshold. 9. The method as recited in claim 8, wherein, when the absolute value of the quotient is greater than the predetermined threshold, decreasing the quotient. 10. The method as recited in claim 1, wherein generating the weight from the summations of the I/Q data streams comprises generating the weight, W, from the quotient including the summations of the I/Q data streams, ΣM and ΣA, by the equation: W=ΣM/(ΣA+δ); wherein δ comprises a predetermined constant. 11. A method for suppressing clutter when detecting targets of interest in a radar system comprising an antenna system and at least two receive beams, the method comprising: receiving I/Q data streams from each of the at least two receive beams, each of the I/Q data streams associated with range bins and including data representing clutter;generating a weight from summations of the I/Q data streams for each of the range bins;applying the generated weight to at least one of the I/Q data streams to provide at least one weighted I/Q data stream;combining the at least one weighted I/Q data stream with one of the other I/Q data streams to thereby generate at least one weighted I/Q data stream representing spatial nulling of clutter for each of the range bins;Doppler filtering the at least one weighted I/Q data stream for each of the range bins to generate at least one Doppler-filtered, spatially-nulled data stream having suppressed clutter for the range bins; andusing the at least one Doppler-filtered, spatially-nulled data stream having suppressed clutter for the range bins to detect targets. 12. The method as recited in claim 11, wherein generating the weight comprises computing the weight based on a summation of the I/Q data streams across pulses for each of the I/Q data streams. 13. The method as recited in claim 11, wherein the at least two receive beams comprise at least a main beam and an auxiliary beam. 14. The method as recited in claim 11, wherein the method further comprises comparing at least one of the summations of the I/Q data streams to a predetermined threshold. 15. The method as recited in claim 14, wherein, when the at least one of the summations exceeds the predetermined threshold, equating the weight to zero. 16. The method as recited in claim 11, wherein the method further comprises comparing an absolute value of the weight to a predetermined threshold. 17. The method as recited in claim 16, wherein generating the weight from the summations of the I/Q data streams comprises generating the weight from a quotient including the summations of the I/Q data streams, and wherein, when the absolute value of the quotient exceeds the predetermined threshold weight, decreasing the quotient. 18. The method as recited in claim 16, wherein generating the weight from the summations of the I/Q data streams comprises equating the weight to a quotient of one of the summations of the I/Q data streams divided by a sum of another of the summations of the I/Q data streams and a predetermined constant, and wherein comparing the absolute value of the weight to the predetermined threshold comprises comparing the absolute value of the quotient to the predetermined threshold. 19. The method as recited in claim 18, wherein, when the absolute value of the quotient is greater than the predetermined threshold, decreasing the quotient. 20. The method as recited in claim 11, wherein generating the weight from the summations of the I/Q data streams comprises generating the weight, W, from the quotient including the summations of the I/Q data streams, ΣM and ΣA, by the equation: W=ΣM/(ΣA+δ); wherein δ comprises a predetermined constant.