System and method for detecting ballistic targets

What is claimed is: 1. A radar system, comprising: a receive antenna configured to receive a receive signal reflected from a ballistic target, the receive signal exhibiting a Doppler shift according to motion of the ballistic target; and a detector implementing a set of matched filters each configured to determine a measure of correlation between the Doppler shift of the receive signal and one of a set of pre-stored Doppler shifts, wherein each of the pre-stored Doppler shifts respectively represents the Doppler shift of a ballistic target passing the antenna at a different speed or a distance of a point of closest approach; wherein the detector is configured to compare the output of at least a first matched filter of the set of matched filters to a threshold to determine whether the output is indicative of a match between the receive signal and the pre-stored Doppler shift of the first matched filter, is further configured to determine an estimated trajectory of the ballistic target based on an azimuth-angle estimation algorithm, upon determining that the output of at least the first matched filter exceeds the threshold, and is further configured to correct the estimated trajectory of the ballistic target according to at least one of an estimated speed or an estimated distance of the point of closest approach, wherein the estimated speed or the estimated distance of the point of closest approach is based, at least in part, on the speed or the distance of the point of closest approach represented by the Doppler shift of the first matched filter. 2. The radar system of claim 1 , wherein the detector is further configured to estimate a point of origin of according to, at least, the estimated trajectory of the ballistic target. 3. The radar system of claim 1 , wherein the azimuth-angle estimation algorithm is one of amplitude-comparison monopulse, phase-comparison monopulse, full vector monopulse, or maximum likelihood estimation. 4. The radar system of claim 1 , wherein the estimated speed is determined by interpolating the speed represented by the Doppler shift of the first matched and a speed represented by a second matched filter, wherein an output of the second matched filter exceeds the threshold. 5. The radar system of claim 1 , wherein the estimated distance of the point of closest approach is determined by interpolating the distance of the point of closest approach represented by the Doppler shift of the first matched and a speed represented by a second matched filter, wherein an output of the second matched filter exceeds the threshold. 6. The radar system of claim 1 , wherein the radar system is a continuous-wave radar. 7. The radar system of claim 1 , wherein the radar system is a pulsed radar. 8. A method for detecting a ballistic target with a radar system, comprising the steps of: receiving with an antenna a receive signal reflected from a ballistic target, the receive signal exhibiting a Doppler shift according to motion of the ballistic target; determining a measure of correlation between the Doppler shift of the receive signal and each of a set of pre-stored Doppler shifts, wherein each of the pre-stored Doppler shifts respectively represents the Doppler shift of a ballistic target passing the antenna at a different speed or a distance of a point of closest approach; comparing the measure of correlation between the receive signal and at least a first pre-stored Doppler shift of the set of pre-stored Doppler shifts to a threshold to determine whether the measure of correlation is indicative of a match between the receive signal and the first pre-stored Doppler shift; determining an estimated trajectory of the ballistic target based on an azimuth-angle estimation algorithm, upon determining that the measure of correlation between the receive signal and at least the first pre-stored Doppler shift of the set of pre-stored Doppler shifts exceeds the threshold; and correcting the estimated trajectory of the ballistic target according to at least one of an estimated speed or an estimated distance of the point of closest approach, wherein the estimated speed or the estimated distance of the point of closest approach is based, at least in part, on the speed or the distance of the point of closest approach represented by the first pre-stored Doppler shift. 9. The method of claim 8 , further comprising the step of estimating a point of origin of according to, at least, the estimated trajectory of the ballistic target. 10. The method of claim 8 , wherein the azimuth-angle estimation algorithm is one of amplitude-comparison monopulse, phase-comparison monopulse, full vector monopulse, or maximum likelihood estimation. 11. The method of claim 8 , wherein the estimated speed is determined by interpolating the speed represented by the first pre-stored Doppler shift and a speed represented by a second pre-stored Doppler shift, wherein the measure of correlation between the receive signal and the second pre-stored Doppler shift exceeds the threshold. 12. The method of claim 8 , wherein the estimated distance of the point of closest approach is determined by interpolating the distance of the point of closest approach represented by the first pre-stored Doppler shift and a distance of the point of closest approach represented by a second pre-stored Doppler shift, wherein the measure of correlation between the receive signal and the second pre-stored Doppler shift exceeds the threshold. 13. The method of claim 8 , wherein the radar system is a continuous-wave radar. 14. The method of claim 8 , wherein the radar system is a pulsed radar.