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A method of operating a pulse-Doppler radar system includes the steps of generating a plurality waveforms, with each waveform comprising a plurality of pulses generated with a staggered pulse repetition frequency (PRF) from pulse to pulse. Received reflected return signals from the generated plurali

A method of operating a pulse-Doppler radar system includes the steps of generating a plurality waveforms, with each waveform comprising a plurality of pulses generated with a staggered pulse repetition frequency (PRF) from pulse to pulse. Received reflected return signals from the generated plurality of waveforms are filtered by a plurality of Doppler filters that span an entire required Doppler visibility range.

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1. A pulse-Doppler radar system, comprising: a transmitter configured to generate and transmit a waveform comprising a plurality of pulses generated with a staggered pulse repetition frequency from pulse to pulse;a receiver configured to receive reflected radar signals and convert the received radar

1. A pulse-Doppler radar system, comprising: a transmitter configured to generate and transmit a waveform comprising a plurality of pulses generated with a staggered pulse repetition frequency from pulse to pulse;a receiver configured to receive reflected radar signals and convert the received radar signals to complex digital received data;a plurality of Doppler filters spanning an entire required Doppler visibility range and configured to filter the complex digital received data into complex digital output data; anda processor configured to perform target detection of objects of interest based on the power of the complex digital output data by summing the squares of the real and imaginary components of the complex digital output data at each range/Doppler cell,wherein the plurality of Doppler filters span at least a range defined between: a predetermined object to range rate (Rdot) of the system, and(−1)×(the predetermined Rdot). 2. The system of claim 1, wherein the powers of the complex digital output data at each range/Doppler cell from two or more bursts are summed prior to target detection, wherein each burst is at a different transmitter frequency to enhance Swerling II detection performance. 3. The system of claim 2, wherein the processor is further configured to perform constant false alarm rate processing by comparing the combined powers of each range/Doppler cell to a background clutter map, yielding Swerling II detection statistics. 4. The system of claim 1, wherein the processor is further configured to perform constant false alarm rate processing by comparing the powers of each range/Doppler cell to a background clutter map, yielding Swerling I detection statistics. 5. A pulse-Doppler radar system, comprising: a transmitter configured to generate and transmit a waveform comprising a plurality of pulses generated with a staggered pulse repetition frequency from pulse to pulse;a receiver configured to receive reflected radar signals and convert the received radar signals to complex digital received data;a plurality of Doppler filters spanning an entire required Doppler visibility range and configured to filter the complex digital received data into complex digital output data; anda processor configured to perform target detection of objects of interest based on the power of the complex digital output data by summing the squares of the real and imaginary components of the complex digital output data at each range/Doppler cell,wherein the plurality of Doppler filters are each configured at a specific object to range rate (Rdot) across the entire required Doppler range to reject stationary and wideband clutter while passing the specific Rdot. 6. The system of claim 5, wherein the plurality of Doppler filter are further configured to reject stationary and wideband clutter while passing the specific Rdot for each unique set of pulse repetition frequency staggers and each transmitter frequency. 7. The system of claim 5, wherein the plurality of Doppler filters span at least a range defined between: a predetermined Rdot of the system, and(−1)×(the predetermined Rdot). 8. The system of claim 5, wherein the powers of the complex digital output data at each range/Doppler cell from two or more bursts are summed prior to target detection, wherein each burst is at a different transmitter frequency to enhance Swerling II detection performance. 9. The system of claim 8, wherein the processor is further configured to perform constant false alarm rate processing by comparing the combined powers of each range/Doppler cell to a background clutter map, yielding Swerling II detection statistics. 10. The system of claim 5, wherein the processor is further configured to perform constant false alarm rate processing by comparing the powers of each range/Doppler cell to a background clutter map, yielding Swerling I detection statistics. 11. A method of operating a pulse-Doppler radar system, the method comprising the steps of: generating a waveform comprising a plurality of pulses generated with a staggered pulse repetition frequency (PRF) from pulse to pulse;receiving reflected return signals from the generated waveform;Doppler filtering the received return signals by a plurality of Doppler filters spanning an entire required Doppler visibility range to generate complex digital output data; andperforming target detection of objects of interest based on the power of the complex digital output data by summing the squares of the real and imaginary components of the complex digital output data at each range/Doppler cell,wherein the plurality of Doppler filters span at least a range defined between: a predetermined object to range rate (Rdot) of the system, and(−1)×(the predetermined Rdot). 12. The method of claim 11, further comprising the step of summing the powers of the complex digital output data at each range/Doppler cell from two or more bursts prior to target detection, wherein each burst is at a different transmitter frequency to enhance Swerling II detection performance. 13. The method of claim 12, wherein the step of performing target detection of objects of interest comprises performing constant false alarm rate processing by comparing the combined powers of each range/Doppler cell to a background clutter map, yielding Swerling II detection statistics. 14. The method of claim 11, wherein the step of performing target detection of objects of interest comprises performing constant false alarm rate processing by comparing the powers of each range/Doppler cell to a background clutter map, yielding Swerling I detection statistics. 15. A method of operating a pulse-Doppler radar system, the method comprising the steps of: generating a waveform comprising a plurality of pulses generated with a staggered pulse repetition frequency (PRF) from pulse to pulse;receiving reflected return signals from the generated waveform;Doppler filtering the received return signals by a plurality of Doppler filters spanning an entire required Doppler visibility range to generate complex digital output data; andperforming target detection of objects of interest based on the power of the complex digital output data by summing the squares of the real and imaginary components of the complex digital output data at each range/Doppler cell,wherein the step of Doppler filtering the received return signals comprises filtering using Doppler filters each configured at specific object to range rates (Rdots) across the entire required Doppler range. 16. The method of claim 15, wherein the plurality of Doppler filter are further configured to reject stationary and wideband clutter while passing the specific Rdot for each unique set of pulse repetition frequency staggers and each transmitter frequency. 17. The method of claim 15, wherein the plurality of Doppler filters span at least a range defined between: a predetermined Rdot of the system, and(−1)×(the predetermined Rdot). 18. The method of claim 15, further comprising the step of summing the powers of the complex digital output data at each range/Doppler cell from two or more bursts prior to target detection, wherein each burst is at a different transmitter frequency to enhance Swerling II detection performance. 19. The method of claim 18, wherein the step of performing target detection of objects of interest comprises performing constant false alarm rate processing by comparing the combined powers of each range/Doppler cell to a background clutter map, yielding Swerling II detection statistics. 20. The method of claim 15, wherein the step of performing target detection of objects of interest comprises performing constant false alarm rate processing by comparing the powers of each range/Doppler cell to a background clutter map, yielding Swerling I detection statistics.