In one aspect, a method includes representing a range of Doppler frequency offsets as a local oscillator waveform comprising a plurality of digital waveform samples, selecting a portion of the plurality of digital waveform samples using a Doppler value to form an optical heterodyne; and generating a
In one aspect, a method includes representing a range of Doppler frequency offsets as a local oscillator waveform comprising a plurality of digital waveform samples, selecting a portion of the plurality of digital waveform samples using a Doppler value to form an optical heterodyne; and generating a signal associated with a target within a bandwidth of a receiver using the optical heterodyne.
대표청구항▼
1. A method, comprising: representing a range of Doppler frequency offsets as a local oscillator waveform comprising a plurality of digital waveform samples;selecting a portion of the plurality of digital waveform samples using a Doppler value to form an optical heterodyne; andgenerating a signal as
1. A method, comprising: representing a range of Doppler frequency offsets as a local oscillator waveform comprising a plurality of digital waveform samples;selecting a portion of the plurality of digital waveform samples using a Doppler value to form an optical heterodyne; andgenerating a signal associated with a target within a bandwidth of a receiver using the optical heterodyne. 2. The method of claim 1, further comprising: determining a velocity of a platform;determining a squint angle between a line from a LADAR sensor disposed on the platform to the target and a nadir axis; anddetermining a Doppler value using the velocity of the platform, a wavelength of the LADAR sensor and the squint angle. 3. The method of claim 2, further comprising: determining an estimated position of the LADAR sensor; anddetermining a location of the target;wherein determining a squint angle comprises determining an estimate of the squint angle using the estimated position of the LADAR sensor and the location of the target. 4. The method of claim 3 wherein determining the estimated position of the LADAR sensor comprises determining the estimated position of the LADAR sensor using a GPS receiver, and wherein determining the velocity of the platform comprises determining an estimated velocity of the platform using the GPS receiver. 5. The method of claim 2 wherein determining a Doppler value comprises determining an estimate Doppler value using the estimated velocity of the platform, a wavelength of the LADAR sensor and the estimate of the squint angle. 6. The method of claim 5 wherein determining an estimate of the Doppler value comprises determining an estimate of the Doppler value, fDE, equal to: fDE=(2VPE/λL)(cos θSE),where VPE is the estimated velocity of the sensor platform, θSE is the estimate of the squint angle, and λL is the wavelength of the LADAR sensor. 7. The method of claim 5, further comprising determining an estimated range to target based on the location of the target and the estimated position of the LADAR sensor. 8. An article comprising: a non-transitory machine-readable medium that stores executable instructions, the instructions causing a machine to: represent a range of Doppler frequency offsets as a local oscillator waveform comprising a plurality of digital waveform samples;select a portion of the plurality of digital waveform samples using a Doppler value to form an optical heterodyne; andgenerate a signal associated with a target within a bandwidth of a receiver using the optical heterodyne. 9. The article of claim 8, further comprising instructions causing the machine to: determine a velocity of a platform;determine a squint angle between a line from a LADAR sensor disposed on the platform to the target and a nadir axis; anddetermine the Doppler value using the velocity of the platform, a wavelength of the LADAR sensor and the squint angle. 10. The article of claim 9, further comprising instructions causing the machine to: determine an estimated position of the LADAR sensor; anddetermine a location of the target;wherein the instructions causing the machine to determine a squint angle comprises instructions causing the machine to determine an estimate of the squint angle using the estimated position of the LADAR sensor and the location of the target. 11. The article of claim 10 wherein the instructions causing the machine to determine the estimated position of the LADAR sensor comprises instructions causing the machine to deter nine the estimated position of the LADAR sensor using a GPS receiver, and wherein the instructions causing the machine to determine the velocity of the platform comprises instructions causing the machine to determine an estimated velocity of the platform using the GPS receiver. 12. The article of claim 11 wherein the instructions causing the machine to determine a Doppler value comprises instructions causing the machine to determine an estimate Doppler value using the estimated velocity of the platform, a wavelength of the LADAR sensor and the estimate of the squint angle. 13. The article of claim 12 wherein the instructions causing the machine to determine an estimate of the Doppler value comprises instructions causing the machine to determine an estimate of the Doppler value, fDE, equal to: fDE=(2VPE/λL)(cos θSE),where VPE is the estimated velocity of the sensor platform, θSE is the estimate of the squint angle, and λL is the wavelength of the LADAR sensor. 14. An apparatus, comprising: circuitry to: represent a range of Doppler frequency offsets as a local oscillator waveform comprising a plurality of digital waveform samples;select a portion of the plurality of digital waveform samples using a Doppler value to form an optical heterodyne; andgenerate a signal associated with a target within a bandwidth of a receiver using the optical heterodyne. 15. The apparatus of claim 14 wherein the circuitry comprises at least one of a processor, a memory, programmable logic and logic gates. 16. The apparatus of claim 14, further comprising circuitry to: deter nine a velocity of a platform;determine a squint angle between a line from a LADAR sensor disposed on the platform to a target and a nadir axis; anddetermine the Doppler value using the velocity of the platform, a wavelength of the LADAR sensor and the squint angle. 17. The apparatus of claim 16, further comprising circuitry to: determine an estimated position of the LADAR sensor; anddetermine a location of the target;wherein the circuitry to determine a squint angle comprises circuitry to determine an estimate of the squint angle using the estimated position of the LADAR sensor and the location of the target. 18. The apparatus of claim 17 wherein the circuitry to determine the estimated position of the LADAR sensor comprises circuitry to determine the estimated position of the LADAR sensor using a GPS receiver, wherein the circuitry to determine the velocity of the platform circuitry to determine an estimated velocity of the platform using the GPS receiver. 19. The apparatus of claim 18 wherein the circuitry to determine a Doppler value comprises circuitry to determine an estimate Doppler value using the estimated velocity of the platform, a wavelength of the LADAR sensor and the estimate of the squint angle. 20. The apparatus of claim 19 wherein the circuitry to determine an estimate of the Doppler value comprises circuitry to determine an estimate of the Doppler value, fDE, equal to: fDE=(2VPE/λL)(cos θSE),where VPE is the estimated velocity of the sensor platform, θSE is the estimate of the squint angle, and λL is the wavelength of the LADAR sensor.
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