초록 ▼

A radar system tracks targets, and for each target determines the maximum acceleration of the target which can be tracked. The target acceleration is compared with the maximum acceleration that the radar can maintain in track, and if the decision is that the radar cannot maintain track, the radar da

A radar system tracks targets, and for each target determines the maximum acceleration of the target which can be tracked. The target acceleration is compared with the maximum acceleration that the radar can maintain in track, and if the decision is that the radar cannot maintain track, the radar data rate is increased, at least for that target. In at least some cases in which the target acceleration is such that the target can be maintained in track, the data rate for that target is decreased.

대표청구항 ▼

1. A method for operating a radar system operable in target tracking mode, said method comprising the steps of: transmitting electromagnetic energy into space by way of an antenna;receiving reflected energy from a target;processing said reflected energy to start a new track or to update an existing

1. A method for operating a radar system operable in target tracking mode, said method comprising the steps of: transmitting electromagnetic energy into space by way of an antenna;receiving reflected energy from a target;processing said reflected energy to start a new track or to update an existing track;examining motion of said target to determine if the target is maneuvering;if said target is identified as not maneuvering, assigning a first selected target update time; andif said target is identified as maneuvering, assigning a second selected target update time, wherein said second selected target update time is less than said first selected target update time. 2. The method of claim 1, wherein the transmitting, receiving, processing, examining and assigning steps are repeatedly performed such that radar resources used for the target oscillate about a value that keeps the target in track and leaves a maximum amount of radar resources available for other targets. 3. The method of claim 2, wherein said receiving step comprises receiving reflected energy from a plurality of targets, and said processing, examining and assigning steps are performed for each target of said plurality of targets such that different target update times will be assigned to different ones of said plurality of targets. 4. The method of claim 3, wherein said repeated assigning steps oscillates radar resources used for at least one of said plurality of targets. 5. A method for operating a radar system operable in target tracking mode, said method comprising the steps of: transmitting electromagnetic energy into space by way of an array antenna at a controllable data rate;receiving reflected energy from a target;processing said reflected energy to start a new track or to update an existing track;examining motion of said target to determine if the target is boosting or ballistic maneuvering;if said motion of said target is ballistic maneuvering, assigning a first selected target update time;if said motion of said target is identified as boosting maneuvering, assigning a second selected target update time, wherein said second selected target update time is less than said first selected target update time. 6. The method of claim 5, wherein the transmitting, receiving, processing, examining and assigning steps are repeatedly performed such that radar resources used for the target oscillate about a value that keeps the target in track and leaves a maximum amount of radar resources available for other targets. 7. The method of claim 6, wherein said receiving step comprises receiving reflected energy from a plurality of targets, and said processing, examining and assigning steps are performed for each target of said plurality of targets such that different target update times will be assigned to different ones of said plurality of targets. 8. The method of claim 7, wherein said repeated assigning steps oscillates radar resources used for at least one of said plurality of targets. 9. A method for operating a radar system which includes a transmitter, a receiver, and processing for generating target tracks, said radar system having a look rate, said method comprising the steps of: operating said radar with a selected antenna beamwidth, look rate, and standard deviation of angular error, to generate target track information;determining the range of each of a plurality of targets;determining at least a tracker containment probability factor, a containment probability confidence factor of the filter error, a filter lag, and filter gains;determining a maximum target maneuver radar capability;if the maximum target maneuver radar capability is exceeded by a target of said plurality of targets, increasing a pulse rate to thereby increase the maximum target maneuver radar capability. 10. The method of claim 9, wherein the maximum target maneuver radar capability is based on at least the containment probability factor and the antenna beamwidth. 11. The method of claim 9, wherein the step of determining a maximum target maneuver radar capability is performed using an iterative numeric method. 12. The method of claim 11, wherein the iterative numeric method is a Picard method or a Newton-Raphson method. 13. The method of claim 9, wherein if the maximum target maneuver radar capability is not exceeded by a target of said plurality of targets, decreasing a pulse rate. 14. The method of claim 13, wherein the step of decreasing a pulse rate frees up radar resources from that one target for use with other targets. 15. The method of claim 14, wherein the steps of increasing a pulse rate and decreasing a pulse rate oscillates radar resources used for at least one of said plurality of targets. 16. A tracking radar system for transmitting electromagnetic signals toward a plurality of tracked targets and for receiving and processing reflected signals to determine at least a location of each of said plurality of tracked targets, said radar system comprising: a transmitter/receiver including an antenna, an exciter, and a controllable beam scheduler, for illuminating said tracked targets at a rate established by the beam scheduler;a track processor coupled to said transmitter/receiver, for determining acceleration of each target in track;a radar resource evaluator coupled to said track processor for determining a maximum target acceleration which can be maintained in track for each target;an acceleration comparator coupled to said track processor and to said resource evaluator, for deciding whether each of said plurality of targets can be maintained in track; anda data rate selector controlling said beam scheduler in response to said decision to increase said radar resources available for tracking at least some of said targets for which said decision is negative. 17. A radar system according to claim 16, wherein said data rate selector increases a beam schedule rate for at least some of said targets for which said decision is negative. 18. A radar system according to claim 16, wherein said data rate selector decreases a beam schedule rate for at least some of said targets for which said decision is positive. 19. A radar system according to claim 16, wherein said radar resource evaluator includes processing which solves the following expression for the maximum target acceleration A that the radar system can track Aj+1=R⁡(BW)(τj+T)2-2⁢K⁢⁢σMτj⁡(τj+T) where τj=T15⁡(3⁢n⁢⁢σM2⁢Aj)25 and: R is radar slant range;BW is antenna beamwidth;K is containment probability factor;n is a filter factor;σM is measurement error standard deviation;τ is filter lag; andT is the data rate. 20. The system of claim 16, wherein said acceleration comparator outputs a “can-track”/“can't track” decision, wherein a “can-track” decision indicates that the target can be maintained in track using a current beam schedule rate, and a “can't-track decision” indicates that the target cannot be maintained in track using the current beam schedule rate.