Millimeter wave and infrared sensor in a common receiving aperture

US 5,214,438 A
Filed: 08/09/1991
Issued: 05/25/1993
Est. Priority Date: 05/11/1990
Status: Expired due to Fees

First Claim

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1. An infrared (IR) and millimeter wave (MMW) common aperture antenna for transmitting MMW energy to space and for receiving MMW and IR energy from space through said common aperture comprising:

an apertured primary parabolic reflector having a reflective front surface sized for defining said common aperture, said primary reflector for reflecting infrared and millimeter wave energy impinging thereon, said primary reflector having a central opening, a central axis passing therethrough, and a focus spaced from the reflective surface on the axis;

a millimeter wave feed assembly having a feed horn located on the axis in the vicinity of the focus of the primary reflector for feeding millimeter wave energy for transmission along a path from the feed horn to the front surface of the primary reflector for reflection therefrom to space and for receiving millimeter wave energy from space reflected from the primary reflector along the path to the feed horn; and

a dichroic element having front and rear surfaces non-uniformly spaced apart and being shaped for defining a millimeter wave lens, said dichroic element being located in the path between the feed horn and the primary reflector having an axis coaxial with the primary reflector, the front surface of said dichroic element being selectively reflective and facing the front surface of the primary reflector, said front surface of the dichroic element having a secondary focus on said axis therebetween for reflecting infrared energy from space reflected from the primary reflector towards the secondary focus, said dichroic element being substantially transparent to MMW energy and having a focus on the axis between the rear surface of the dichroic element and the millimeter wave feed assembly, said millimeter wave lens for re-focusing said millimeter wave energy without significant attenuation.

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Abstract

The present invention is an integrated millimeter wave (MMW) and an infrared (IR) common aperture sensor employing a common primary reflector for infrared and millimeter wave energy. An active transmitter/receiver millimeter wave horn assembly located at the focus of the primary mirror transmits and receives millimeter wave signals off the primary reflector. A selectively coated dichroic element is located in the path of the millimeter wave energy on the axis between the feed and the primary reflector. The dichroic element reflects infrared energy from the primary reflector to a focal point and at the same time transmits and focuses millimeter wave energy. An optical system relays the infrared energy to a focal plane behind the primary mirror. The dichroic element transmits and focuses millimeter wave energy without significant attenuation such that optical and millimeter wave energy may be employed on a common boresight. Improvements in the feed assembly include a four channel waveguide structure capable of azimuth and elevation determination in sum and difference configurations. A baffle and cold stop shields the optical system from unwanted infrared radiation. Electrical transmit and receive circuitry and a correction circuit provide high probability of detection and low false alarm rate.

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29 Claims

1. An infrared (IR) and millimeter wave (MMW) common aperture antenna for transmitting MMW energy to space and for receiving MMW and IR energy from space through said common aperture comprising:
- an apertured primary parabolic reflector having a reflective front surface sized for defining said common aperture, said primary reflector for reflecting infrared and millimeter wave energy impinging thereon, said primary reflector having a central opening, a central axis passing therethrough, and a focus spaced from the reflective surface on the axis;
  
  a millimeter wave feed assembly having a feed horn located on the axis in the vicinity of the focus of the primary reflector for feeding millimeter wave energy for transmission along a path from the feed horn to the front surface of the primary reflector for reflection therefrom to space and for receiving millimeter wave energy from space reflected from the primary reflector along the path to the feed horn; and
  
  a dichroic element having front and rear surfaces non-uniformly spaced apart and being shaped for defining a millimeter wave lens, said dichroic element being located in the path between the feed horn and the primary reflector having an axis coaxial with the primary reflector, the front surface of said dichroic element being selectively reflective and facing the front surface of the primary reflector, said front surface of the dichroic element having a secondary focus on said axis therebetween for reflecting infrared energy from space reflected from the primary reflector towards the secondary focus, said dichroic element being substantially transparent to MMW energy and having a focus on the axis between the rear surface of the dichroic element and the millimeter wave feed assembly, said millimeter wave lens for re-focusing said millimeter wave energy without significant attenuation.
- View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20)
- - 2. The apparatus of claim 1 further comprising an optical detector located behind the primary reflector and optical means having an optical path being located on the central axis of the primary reflector between the secondary focus and the optical detector for relaying the infrared energy reflected from the dichroic element to said optical detector along said central axis.
  - 3. The apparatus of claim 2 further comprising an optical baffle between the optical means and the dichroic element for shielding the optical means from unwanted infrared energy.
  - 4. The apparatus of claim 2 further comprising cold stop means in the form of an apertured plate located in the optical path adjacent the optical detector, said cold stop means having aperture therein, being sized in accordance with the optical means so as to be optically equivalent to the common aperture for shielding the optical detector from optical energy which does not fall within the common aperture.
  - 5. The apparatus of claim 1 further comprising a waveguide means for relaying millimeter wave energy between the feed horn and a millimeter wave energy processing location.
  - 6. The apparatus of claim 1 wherein the feed horn comprises:
    - four symmetrical millimeter wave feed channels directed in opposite pairs at the primary reflector, each opposite pair located on an axis parallel with the central axis of the primary reflector establishing sum and difference channels for transmitting and receiving circularly polarized millimeter wave energy in elevation and azimuth;
      
      comparator means for phase shifting the millimeter wave energy in the difference channel 180°
      
      with respect to the sum channel for each of the elevation and azimuth;
      
      polarizer means including a corresponding polarizer for each feed channel for circularly polarizing the millimeter wave energy in each channel.
  - 7. The apparatus of claim 1 further comprising:
    - mounting means for securing the primary reflector in spaced relationship with the dichroic element.
  - 8. The apparatus of claim 7 wherein the mounting means comprises a base portion for supporting the primary reflector;
    - a support ring for receiving the dichroic element therein; and
      
      a plurality of radial support struts extending from the support ring for attachment with the primary reflector support near a marginal edge thereof.
  - 9. The apparatus of claim 8 wherein the support struts are integrally formed with the support ring and are symmetrically disposed with respect to the axis of the reflector.
  - 10. The apparatus of claim 9 further comprising a plurality of waveguides, one for each support strut, said waveguides and struts being located in adjacent axial spaced relationship about the central axis of the primary reflector for reducing shading of the primary reflector.
  - 11. The apparatus of claim 7 wherein the mounting means comprises waveguide means having end portions coupled to the feed horn for supporting the feed horn in spaced relation to the primary reflector and a support ring for the dichroic element.
  - 12. The apparatus of claim 1 further comprising optical means including a cylindrical housing extending through the opening in the primary reflector and being coaxial therewith and optical elements located in the cylindrical housing along the central axis;
    - said housing having an input opening spaced from the dichroic element, the optical elements being in recessed space relationship with respect to the input opening within the housing.
  - 13. The apparatus of claim 12 wherein the housing further includes a tapered end portion extending from the input opening towards the primary reflector for providing clearance for the millimeter wave energy travelling along the path between the primary reflector and the feed horn.
  - 14. The apparatus of claim 1 wherein the feed assembly comprises a plurality of axially stacked apertured discs coaxially located along the central axis of the primary reflector for guiding millimeter wave energy through the feed assembly the disks having apertures therein forming sum and difference channels in the fed assembly for establishing azimuth and elevation and circular polarization of the millimeter wave energy.
  - 15. The apparatus of claim 1 further comprising circuit means for transmitting and receiving millimeter wave energy to and from the feed horn.
  - 16. Apparatus of claim 15 further comprising infrared and millimeter wave processing circuit means responsive to IR and MMW energy for processing the IR and MMW energy into IR and MMW image signals and correlation circuit means responsive to the processing means for superimposing and correlating the IR and MMW image signals for enhanced imaging accuracy.
  - 17. The apparatus of claim 1 wherein the primary reflector and the dichroic element are in a cassegrain configuration.
  - 18. The apparatus of claim 1 wherein the dichroic element has a dichroic coating for reflecting infrared and transmitting millimeter wave energy.
  - 19. The apparatus of claim 1 further comprising radome means substantially transparent to IR and millimeter wave energy for covering the aperture.
  - 20. The apparatus of claim 6 further comprising waveguide means coupled to the feed horn including at least one corresponding waveguide for carrying MMW energy to each feed channel.

21. A millimeter wave and infrared common imaging aperture for transmitting and receiving of MMW energy to and from space and for receiving IR energy for space comprising:
- a primary parabolic reflector for reflecting optical and millimeter wave energy, said primary reflector having a central axis and a focus on the axis opposite the reflector;
  
  a feed assembly having a feed horn located on the axis in the vicinity of the focus for feeding millimeter wave energy along a path to the primary reflector for transmission to space and for receiving from space millimeter wave energy reflected to the focus from the primary reflector along the path;
  
  a dichroic element located facing the primary reflector in the path between the feed assembly and the primary reflector having an axis coaxial therewith and a secondary focus on said axis coaxial therewith and a secondary focus on said axis for reflecting optical energy reflected from the primary reflector towards the secondary focus, said dichroic element being substantially transparent to MMW energy and having non-uniformly spaced apart surfaces for allowing said millimeter wave energy to re-focus onto the feed assembly without significant attenuation;
  
  optical means for relaying the optical energy reflected from the dichroic element to an output focal plane; and
  
  circuit mans responsive to the millimeter wave energy and the optical energy for producing corresponding MMW and optical image signals and correlation means responsive to the circuit means for producing a correlated superimposed image representation of the image signals.
- View Dependent Claims (22, 23, 24, 25, 26)
- - 22. The imaging aperture of claim 21 wherein the circuit means comprises millimeter wave image processing means for producing an object image in the millimeter wave regime and optical processing means producing an optical image in the optical regime and the correlation means comprises combined imaging means for producing a correlated superimposed optical and high frequency image therefrom.
  - 23. The imaging aperture of claim 21 further comprising acquisition logic responsive to the circuit means and the correlation means for producing an acquisition output indicative of a valid image.
  - 24. The imaging aperture of claim 21 wherein the optical means further comprises a focal plane array of pixel elements being alternately line scannable row by row and column by column and pixel element by pixel element.
  - 25. The imaging aperture of claim 24 wherein the line scan of rows and columns of the focal plane array is relatively faster than pixel element by pixel element scanning.
  - 26. The imaging aperture of claim 24 wherein the feed assembly comprises a millimeter wave energy waveguide operating in elevation and azimuth modes.

27. A method for imaging employing a common aperture in diverse spectral regions comprising the steps of:
- transmitting and receiving millimeter wave (MMW) signals along a path by means of a primary reflector, and a MMW transceiver positioned in confronting relation along an optical axis of the primary reflector;
  
  focusing the MMW signals by means of a transparent millimeter wave focusing element located on the optical axis between the transceiver and the primary reflector said focusing element being formed of a lens element having non-uniformly spaced apart surface; and
  
  receiving optical signals reflected by means of the primary reflector and a dichroic element located on the millimeter wave focusing element, which dichroic element is aligned with the optical axis, faces the primary reflector and supports the MMW focusing element in the same path as the millimeter wave signals without significant attenuation of said millimeter wave signals.
- View Dependent Claims (28)
- - 28. The method of claim 27 further comprising generating corresponding images from each of the millimeter wave and optical signals received;
    - andsuperimposing and correlating images for verifying the accuracy of the individual images.

29. An infrared (IR) and millimeter wave (MMW) common aperture antenna for transmitting MMW energy to space and for receiving MW and IR energy from space through said common aperture comprising:
- a primary parabolic reflector having a reflective surface sized for defining said common aperture, said primary reflector for reflecting infrared and millimeter wave energy impinging thereon, said primary reflector having a central opening, a central axis passing therethrough and a focus spaced from the reflective surface on the axis;
  
  a millimeter wave feed assembly having a feed horn located on the axis in the vicinity of the focus of the primary reflector for feeding millimeter wave energy for transmission along the path from the feed horn to the primary reflector for reflection therefrom to space and for receiving millimeter wave energy from space reflected from the primary reflector along the path to the feed horn;
  
  a dichroic element located in the path between the feed horn and the primary reflector having an axis coaxial with the primary reflector, said dichroic element having a selectively reflective surface facing the surface of the primary reflector and a secondary focus on the axis therebetween for reflecting infrared energy from space reflected from the primary reflector towards the secondary focus, said dichroic element being substantially transparent to MMW energy and shaped for focusing said millimeter wave energy towards said millimeter wave feed without significant attenuation; and
  
  optical means including a cylindrical housing extending through the opening int eh primary reflector and being coaxial therewith, and optical elements located in the cylindrical housing along the central axis, said housing having an input opening in spaced relation from the dichroic element, the optical elements being in recessed spaced relationship with respect to the input opening within the housing and the housing includes a tapered end portion extending from the input opening towards the primary reflector for providing clearance for the millimeter wave energy traveling along the path between the primary reflector and the feed horn.

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Current Assignee
Northrop Grumman Corporation
Original Assignee
Westinghouse Electric Company LLC (Brookfield Asset Management Incorporated)
Inventors
Schwerdt, Christopher B., Winterble, William C., Smith, Corbitt T., McCormick, Thomas C., Brusgard, Thomas C., Sijgers, Hendrik K.
Primary Examiner(s)
Hille, Rolf
Assistant Examiner(s)
BROWN, PETER T

Application Number

US07/745,993
Time in Patent Office

655 Days
Field of Search

343/725, 343/720, 343/781 P, 343/781 CA, 343/776-779, 343/786, 343/756, 343/909, 343/911 R, 342/53, 342/363, 342/365, 342/373, 342/176, 342/179, 333/21 A, 333/21 R, 250/332
US Class Current

343/725
CPC Class Codes

F41G 7/008   Combinations of different g...

F41G 7/2213   maintaining the axis of an ...

F41G 7/2246   Active homing systems, i.e....

F41G 7/2253   Passive homing systems, i.e...

F41G 7/2286   using radio waves

F41G 7/2293   using electromagnetic waves...

H01Q 19/132   Horn reflector antennas; Of...

H01Q 21/28   Combinations of substantial...

H01Q 5/22   RF wavebands combined with ...

H01Q 5/45   using two or more feeds in ...

Millimeter wave and infrared sensor in a common receiving aperture

First Claim

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Abstract

232 Citations

29 Claims

Specification

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Millimeter wave and infrared sensor in a common receiving aperture

First Claim

1 Assignment

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0 Petitions

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Accused Products

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Abstract

232 Citations

29 Claims

Specification

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Use Cases

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Others