Bessel beam radar system using sequential spatial modulation

US 5,093,649 A
Filed: 08/28/1990
Issued: 03/03/1992
Est. Priority Date: 08/28/1990
Status: Expired due to Fees

First Claim

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1. A radar system capable of resolving multiple targets within a radar beam width, comprising:

(a) transmitter means for producing a radar signal at a desired wavelength;

(b) antenna means, connected to the transmitter means, for radiating the radar signal as a radar beam along a Poynting vector, and for receiving a reflected signal from each target;

(c) modulation means for periodically varying a position from which the antenna means radiates the radar signal by a fractional wavelength of the radar signal in respect to two orthogonal axes while maintaining a constant spatial polarization for the radar signal, thereby spatially modulating the radar beam; and

(d) a receiver that includes processor means, connected to receive and process the reflected signals from the antenna means, for developing a phase history of the reflected signals, and further operative to derive from the phase history a function that uniquely determines an angular position of each target about the antenna means.

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Abstract

A spatially modulated Bessel beam radar system for enhancing the resolution with which a range and an azimuth of a plurality of closely spaced targets is determined. In a Bessel beam radar system, a Bessel beam is generated by sequential spatial modulation of the radar signal while maintaining a constant spatial polarization, and the return signal from one or more targets is processed to determine its Bessel function content. To spatially modulate the radar beam, the point at which the radar signal is transmitted is moved around a circular orbit. In a first embodiment of the spatially modulated Bessel beam radar system (80), a radar dome (86) mounted on the distal end of a mast (84) is pivoted around an orbit (90). The radar signal is transmitted in a predefined direction, along a Poynting vector that is generally aligned with the plane of the orbit. In a second embodiment (110), a plurality of parabolic antennas (116) are arranged in a spaced-apart circular array around a common center. The radar signal is sequentially spatially modulated as it is transmitted from each of the parabolic antennas in sequence around the circular array, and the Poynting vector of the spatially modulated Bessel beam radar signal is generally transverse to a plane in which the parabolic antennas are disposed. The signal reflected back from plural targets comprises a complex phase history. To determine a range and azimuth for each target, a controller/processor (180), processes this signal to develop closed form Bessel functions from which target azimuth and range are determined. Alternatively, target azimuth is determined from a convolution of the complex phase history using a dot product detector (202).

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27 Claims

1. A radar system capable of resolving multiple targets within a radar beam width, comprising:
- (a) transmitter means for producing a radar signal at a desired wavelength;
  
  (b) antenna means, connected to the transmitter means, for radiating the radar signal as a radar beam along a Poynting vector, and for receiving a reflected signal from each target;
  
  (c) modulation means for periodically varying a position from which the antenna means radiates the radar signal by a fractional wavelength of the radar signal in respect to two orthogonal axes while maintaining a constant spatial polarization for the radar signal, thereby spatially modulating the radar beam; and
  
  (d) a receiver that includes processor means, connected to receive and process the reflected signals from the antenna means, for developing a phase history of the reflected signals, and further operative to derive from the phase history a function that uniquely determines an angular position of each target about the antenna means.
- View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9, 10, 11)
- - 2. The radar system of claim 1, wherein the antenna means include a pair of accelerometers mounted to monitor acceleration along the two orthogonal axes, producing signals used by the processor means for correlating antenna position with the phase of the reflected signals to develop the phase history.
  - 3. The radar system of claim 1, wherein the antenna means comprise a plurality of spaced-apart antennas arranged in a circular array, each antenna being connected to the transmitter means to transmit the radar beam from a different point around the circular array.
  - 4. The radar system of claim 1, wherein the modulation means are operative to move the antenna means in a substantially closed orbit.
  - 5. The radar system of claim 1, wherein the positions from which the antenna means radiate the radar signal are substantially coplanar with the Poynting vector.
  - 6. The radar system of claim 1, wherein the positions from which the antenna means radiate the radar signal are substantially transverse to the Poynting vector.
  - 7. The radar system of claim 6, wherein the function developed by the processor means is a Bessel function, which uniquely determines the angular spatial position of each target about the antenna means.
  - 8. The radar system of claim 7, wherein the processor means are operative to produce a Fourier transform of the phase history of the reflected signals to generate spatial frequency domain data and operative to develop the Bessel function from the spatial frequency domain data.
  - 9. The radar system of claim 1, wherein the processor means are further operative to determine a range for each target with a resolution less than twice an effective radius of the modulation means.
  - 10. The radar system of claim 1, wherein the receiver includes antenna dispersion removal means for enhancing the resolution with which the range of each target is determined.
  - 11. The radar system of claim 1, wherein the transmitter means transmits a plurality of pulses, each of the pulses having a different frequency within a band of frequencies, said range of frequencies comprising a synthetic bandwidth for the radar beam, said processor means being operative to process the reflected signals in the frequency domain to determine a range for each of the targets.

12. In a radar system having a radar transmitter and receiver for respectively producing a radar signal and receiving a reflected signal from a target, apparatus for improving the resolution with which the radar system resolves a plurality of closely spaced targets, comprising:
- (a) antenna means connected to the radar transmitter and receiver and operative to transmit a radar beam along a Poynting vector and to receive the reflected signal from the target;
  
  (b) modulation means, connected to the antenna means, for changing a position from which the antenna means transmits the radar beam with respect to two orthogonal axes while maintaining a constant spatial polarization for the radar signal, whereby changing the position from which the radar beam is transmitted from the antenna means spatially modulates the radar beam; and
  
  (c) processing means, connected to receive the reflected signal from the antenna means, for developing a phase history of the reflected signals to derive a Bessel function used in determining an azimuth for each target about the antenna means.
- View Dependent Claims (13, 14, 15, 16, 17, 18, 19, 20, 21)
- - 13. The apparatus of claim 12, wherein the modulation means periodically move the antenna means in a generally vertical, closed orbit.
  - 14. The apparatus of claim 12, wherein the modulation means periodically move the antenna means in a generally horizontal, closed orbit.
  - 15. The apparatus of claim 12, further comprising means for determining the position of the antenna means as it moves and producing a signal indicative of said position.
  - 16. The apparatus of claim 15, wherein the processor means use the signal indicative of said position to develop the phase history and to perform a synthetic aperture integration having a closed form of the Bessel function.
  - 17. The apparatus of claim 12, wherein the antenna means periodically move through a distance that is a fraction of the radar signal wavelength.
  - 18. The apparatus of claim 12, wherein the antenna means comprise a plurality of antennas spaced apart in a circular array, said modulation means being operative to transmit the radar signal from the antennas at different positions around the array.
  - 19. The apparatus of claim 12, wherein the transmitter generates a different frequency pulse within a range of frequencies for transmission from the antenna means to synthesize an increased effective bandwidth for the radar signal to improve the resolution with which a target range is determined by the processor means, and wherein the processor means are operative to produce a Fourier transform of the phase history of the reflected signals to generate spatial frequency domain data, and operative to develop the Bessel function from the spatial frequency domain data.
  - 20. The apparatus of claim 19, wherein the processor means are further operative to compare the spatial frequency domain data to Bessel function phasers developed from a plurality of predetermined Bessel function coefficients to determine a spatial correlation plane relating correlation values to a target location.
  - 21. The apparatus of claim 12, wherein the processor means include antenna dispersion removal means for improving the resolution with which a range from the antenna means to the target is determined.

22. A method for resolving multiple targets separated by less than a radar beam width, for use with a radar system having a radar transmitter, a radar receiver, and antenna means for directing a radar beam along a Poynting vector and receiving a reflected signal from the target, comprising the steps of:
- spatially modulating the radar beam about a closed path by periodically changing the position from which the radar beam is transmitted while maintaining a constant spatial polarization for the radar beam;
  
  processing the reflected signal from the targets to develop phase history data for the reflected signal; and
  
  determining an azimuth for each target about the antenna means as a function of the phase history data.
- View Dependent Claims (23, 24, 25, 26, 27)
- - 23. The method of claim 22, further comprising the steps of transmitting a plurality of pulses from the antenna means, each pulse having a frequency within a predefined range of frequencies;
    - and developing range data for the targets from frequency domain data determined by processing the reflected signal from the targets with a fast Fourier transform processor.
  - 24. The method of claim 22, further comprising the step of removing an antenna dispersion from the reflected signals received by the antenna means, whereby a range for each of the targets from the antenna means is resolved with a selectively variable resolution.
  - 25. The method of claim 22, wherein the step of determining the azimuth includes the step of continuously maintaining a target coherence over multiple periods of spatial modulation.
  - 26. The method of claim 23, wherein the range data are used to generate a range gate signal, which is initially used to detect one or more moving targets in a fixed range cell, and in response, an accumulation of additional range data for each target, further comprising the step of providing a separate movable range cell for tracking the range of each target as it changes.
  - 27. The method of claim 26, wherein the step of determining the azimuth comprises the steps of:
    - producing a Fourier transform of the phase history data of the reflected signals to produce spatial frequency domain data; and
      
      developing a Bessel function from the spatial frequency domain data used to define the azimuth and an azimuth rate for each target.

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Current Assignee
The Boeing Co.
Original Assignee
The Boeing Co.
Inventors
Johnson, Walter J.
Primary Examiner(s)
Tarcza, Thomas H.
Assistant Examiner(s)
Swann, Tod R.

Application Number

US07/573,998
Time in Patent Office

553 Days
Field of Search

342/127, 342/147, 342/25, 342/188, 342/157, 342/148, 342/194, 342/361, 342/442, 342/159
US Class Current

342/157
CPC Class Codes

G01S 13/426   Scanning radar, e.g. 3D rad...

G01S 13/87   Combinations of radar syste...

G01S 13/904   SAR modes

G01S 13/9082   Rotating SAR [ROSAR]

G01S 7/2813   Means providing a modificat...

H01Q 3/10   to produce a conical or spi...

Bessel beam radar system using sequential spatial modulation

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Bessel beam radar system using sequential spatial modulation

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