Circular polarization is converted from linear polarization by splitting the incoming wave into two orthogonal wave vectors that are approximately equal in amplitude and 90 degrees apart in phase. The device that converts polarization from one state to another is often called a polarizer. Such a device may take the form of a waveguide component, a flat layered material placed above an antenna aperture, or as a multiport microwave device.
Some waveguide polarizers are coaxial polarizers. Coaxial polarizers often have dielectric pieces attached to the outer surface of a conductive inner tube of the coaxial waveguide. These dielectric pieces are responsible for creating the 90 degree phase difference in two orthogonal output modes of equal amplitude which leads to circular polarization. In prior art coaxial polarizers, the outer surface of a conductive inner tube of the coaxial waveguide has protrusions and the dielectric pieces have mating indents, by which the dielectric pieces are attached to the protrusions of the conductive inner tube. The conductive inner tubes with protrusions require complex machining processes. Likewise, the dielectric pieces that are mated to the protrusions require complex machining processes.
The present application relates to a coaxial polarizer. The coaxial polarizer includes an outer-conductive tube, an inner-conductive tube positioned within the outer-conductive tube and axially aligned with the outer-conductive tube, and two dielectric bars each having a flat-first surface. The inner-conductive tube has two shallow-cavities on opposing portions of an outer surface of the inner-conductive tube. The shallow-cavities each have at least one planar area. The at least one planar area has a cavity length parallel to a Z axis and has at least one cavity width that is perpendicular to the Z axis and perpendicular to a radial direction of the inner-conductive tube. The at least one cavity width includes a minimum width. The flat-first surface has a dielectric length parallel to the Z axis and a dielectric width perpendicular to the Z axis. The dielectric length is less than the cavity length and the dielectric width is less than the minimum width. Cross-sections of each of the two dielectric bars taken perpendicular to the Z axis have four respective surfaces in a rectangular shape. The two flat-first surfaces of the respective two dielectric bars contact at least a portion of the respective two planar areas of the two shallow-cavities.
The details of various embodiments of the claimed invention are set forth in the accompanying drawings and the description below. Other features and advantages will become apparent from the description, the drawings, and the claims.
Like reference numbers and designations in the various drawings indicate like elements.
The coaxial polarizers described herein are single coaxial waveguide devices with one physical input port and one physical output port. The dielectric pieces are attached to the center conductor of the coaxial waveguide with ease. The machining for the center conductor in the coaxial polarizers described herein is less complex than the machining required for prior art coaxial polarizers. The dielectric pieces attached to the center conductor of the coaxial waveguide create the 90 degree phase difference in two orthogonal output modes of equal amplitude which leads to circular polarization. The dielectric pieces described herein are simpler in shape and therefore simpler to fabricate than the dielectric pieces in prior art coaxial polarizers. Likewise, the method for attaching the dielectric pieces to the center conductor is a convenient and relatively low-cost method compared to prior art methods of making coaxial polarizers. The geometry of the center conductive tube and the specific shape of the dielectric pieces are optimized and the performance, including the input return loss, of the coaxial polarizers is improved by adding a metal ring on the outer surface of the center conductor. When the diameter, length, and distance of the ring from the dielectric bars are optimized in concert with the other variables, excellent return loss and axial ratio are achieved. The steps in embodiments of the dielectric bars described herein and the impedance matching ring result in a coaxial polarizer with reduced length. The compact size of the coaxial polarizer allows antenna feeds to be small enough to meet stringent size constraints especially since other components are also required such as transitions, radiators, and filters. The configurations of dielectric bars and inner conductive tubes described herein permits a flat-first surface of the dielectric to be parallel to and attached to a planar area in a shallow-cavity on the surface of the inner conductive tube.
The coaxial polarizer 10 includes an outer-conductive tube 110 and an inner-conductive tube 130 positioned within the outer-conductive tube 110. The inner-conductive tube 130 is axially aligned with the outer-conductive tube 110 using alignment spacers or features of the system in which the coaxial polarizer 10 is positioned. The inner-conductive tube 130 has a hollow core 131 that is bounded by the inner surface 231 of the inner-conductive tube 130. The input end 145 of the coaxial polarizer 10 is spanned by the X-Y vectors shown in
The inner-conductive tube 130 and the outer-conductive tube 110 are concentrically aligned to each other. The outer surface 230 of the inner-conductive tube 130 is radially offset from the inner surface 211 of the outer-conductive tube 110 by a distance indicted by a double-headed arrow labeled 125. The region between the outer surface 230 of the inner-conductive tube 130 and the inner surface 211 of the outer-conductive tube 110, which is represented generally at 111, supports modes propagating in the Z direction from the input port at the input end 145 to the output port at the output end 146 as known to one skilled in the art. The inner-conductive tube 130 of the coaxial polarizer 10 is hollow to support a second frequency band interior to the coaxial polarizer 10. The hollow core 131 of the inner-conductive tube 130 supports modes propagating in the Z direction from the input port at the input end 145 to the output port at the output end 146 within the hollow core 131. In one implementation of this embodiment, the second frequency band is not required and the inner-conductive tube 130 is a solid metal cylinder.
The outer surface 230 of the inner-conductive tube 130 of the coaxial polarizer 10 of
As shown in
A first shallow-cavity 162-1 is shown in
As shown in
The first-full-planar area 150 of the first shallow-cavity 162-1 also includes a second planar area 322 in a second section 362 of the first shallow-cavity 162-1. The second planar area 322 in the second section 362 is adjoined to and parallel to the first planar area 321 in the first section 361. The second planar area 322 in the second section 362 is perpendicular to the first radial direction r1 (
The first-full-planar area 150 of the first shallow-cavity 162-1 also includes a third planar area 323 in a third section 363 of the first shallow-cavity 162-1. The third planar area 323 in the third section 363 is adjoined to and parallel to the first planar area 321 in the first section 361. The third planar area 323 in the third section 363 is perpendicular to the first radial direction r1 (
The second shallow-cavity 162-2 is similar to the first shallow-cavity 162-1 and is also described with reference to
The second-full-planar area 150′ of the second shallow-cavity 162-2 includes a fourth planar area 321′ in a fourth section 361′ of the second shallow-cavity 162-2. The fourth planar area 321′ in the fourth section 361′ has a fourth-cavity width 180′ equal to a second minimum width 180′. The fourth planar area 321′ of the second shallow-cavity 162-2 is perpendicular to a second radial direction r2 (
The second-full-planar area 150′ of the second shallow-cavity 162-2 also includes a fifth planar area 322′ in a fifth section 362′ of the second shallow-cavity 162-2. The fifth planar area 322′ in the fifth section 362′ is adjoined to and parallel to the fourth planar area 321′ in the fourth section 361′. The fifth planar area 322′ in the fifth section 362′ is perpendicular to the second radial direction r2 (
The second-full-planar area 150′ of the second shallow-cavity 162-2 also includes a sixth planar area 323′ in a sixth section 363′ of the second shallow-cavity 162-2. The sixth planar area 323′ in the sixth section 363′ is adjoined to and parallel to the fourth planar area 321′ in the fourth section 361′. The sixth planar area 323′ in the sixth section 363′ is perpendicular to second radial direction r2 (
In one implementation of this embodiment, the first shallow-cavity 162-1 and the second shallow-cavity 162-2 have the same dimensions. In one implementation of this embodiment, the cavity length 170 of the first shallow-cavity 162-1 equals the cavity length 170′ of the second shallow-cavity 162-2. In another implementation of this embodiment, the cavity width 180 of the first shallow-cavity 162-1 equals the cavity width 180′ of the second shallow-cavity 162-2. In yet another implementation of this embodiment, the first shallow-cavity 162-1 and the second shallow-cavity 162-2 have different shapes. In that case, second shallow-cavity 162-2 is another one of the shapes described herein. In any case, the shallow-cavities 162-1 and 162-2 each have at least one planar area that is perpendicular to a radial direction of the inner-conductive tube 130.
As shown in
The dielectric bars 160-1 and 160-2 each have the shape of two stepped rectangular prisms. Thus, a cross-sectional view of each of the two dielectric bars 160-1 and 160-2 taken perpendicular to the Z axis has four respective surfaces in a rectangular shape. The cross-sectional view of
A flat surface, as used herein, is not necessarily flat to known optical flatness (e.g., flatness is not based on wavelengths). As defined herein a surface is flat if there are small protrusions on the order of 10s of microns. As defined herein, surfaces are parallel to each other even if they subtend planes that intersect at an angle within a few degrees (e.g., parallelism is not based on wavelengths).
The cross-sectional view of
In one implementation of this embodiment, the first dielectric 160-1 and the second dielectric 160-2 have the same shape. In another implementation of this embodiment, the first dielectric 160-1 and the second dielectric 160-2 have different shapes. In that case, second dielectric 160-2 has the shape of any of the other dielectric shapes described herein. In any case, the first dielectric 160-1 and second dielectric 160-2 each have a flat-first surface 260 that is rectangular in shape. The first dielectric 160-1 and the second dielectric 160-2 are placed into the respective minimally oversized shallow-cavities 162-1 and 162-2. As shown in
In one implementation of this embodiment, the shallow-cavities 162-1 and 162-2 are machined on the outer surface 230 of the inner-conductive tube 130, and the first dielectric 160-1 and the second dielectric 160-2 are held in place within the shallow-cavities 162-1 and 162-2 with industrial adhesive. When the first dielectric 160-1 and the second dielectric 160-2 are attached to the inner-conductive tube 130 and enclosed in the outer-conductive tube 110, they do not touch the inner surface 211 (
The capital letter I-shape of the shallow-cavities 162-1 and 162-2 shown in
As shown in
As shown in
As shown in
As shown in
In one implementation of this embodiment, the dielectric bars 162-1 and 162-2 of
The dielectric bar 166 differs from the dielectric bar 160-1 shown in
The first-section-planar area 461 that spans the first plane X1″-Z1″ has a first-cavity width 180 equal to the first-minimum width 180. The first-section-planar area 461 is perpendicular to the first radial direction r1 (
The second-section-planar area 462 that spans the second plane X2″-Z2″ has a second-cavity width 181. The second-section-planar area 462 is perpendicular to the first radial direction r1 (
The coaxial polarizer is designed using a full-wave electromagnetic field solver software package such as ANSYS HFSS, commercially available from ANSYS, Inc., or CST Microwave Studio, commercially available from CST Computer Simulation Technology AB. The coaxial polarizer of this application is useful in dual-frequency concentric antenna feeds. The space 125 must be large enough so that the first frequency band is above the TE11 cutoff frequency for the coaxial waveguide and, hence, electromagnetic waves within this first intended frequency band will propagate in the coaxial waveguide. The circular waveguide diameter must be chosen to be large enough so that the second frequency band is above the TE11 cutoff frequency and, hence, electromagnetic waves within this second intended frequency will propagate in the circular waveguide. The outer tube diameter must be small enough to meet the space constraints of the system in which it is being installed. Additionally, the inner tube wall thickness must be of sufficient size to allow room for the shallow cavities for a chosen dielectric bar width which is also a key parameter in the design. The inner and outer conductor tube diameters and the inner tube wall thickness are typically chosen in advance of computer optimization runs based on the constraints above. Then, the width of the dielectric bars 161-1 and 161-2 and the lengths and thicknesses of the various sections of the dielectric bars are adjusted to optimize the performance of the coaxial polarizer in the first frequency band. Specifically, the goal of the computer controlled optimizer is to find the dielectric bar geometry which minimizes the axial ratio of the polarizer such that the resulting electromagnetic field polarization at the output of the polarizer is circular. Additionally, in some embodiments, the return loss of the input electromagnetic wave may be optimized through adjustment of the geometry and the location of the conductive ring 190 (
In one embodiment of the inner-conductive tube 171 shown in
At block 1402, a first shallow-cavity 162 having at least one first-planar area is machined on an outer-curved surface of a cylindrical piece aligned to an axial direction. As defined herein, a cylindrical piece is either a solid metal cylinder or a metal cylindrical tube. In one implementation of this embodiment, machining is done on a solid metal cylinder and the piece is later machined to bore a hole axially into the solid metal cylinder to form a metal cylindrical tube. In another implementation of this embodiment, the machining is done on a solid metal cylinder and the piece is used for a single frequency band coaxial polarizer.
At block 1404, a second shallow-cavity 162 having at least one second-planar area 162-2 is machined on the outer-curved surface of the cylindrical piece, wherein the first-planar area opposes the second planar area.
In one implementation of this embodiment, the processes at block 1402 and 1404 are performed as follows. A first-planar area is machined in a first section 361 of the first shallow-cavity 162. Then a second-planar area is machined in a second section 362 of the first shallow-cavity 162. Then a third-planar area is machined in a third section 363 of the first shallow-cavity 162. The first-planar area has a length parallel to the axial direction and a width equal to a minimum width. The second-planar area has a second width greater than the minimum width 180. The second-planar area adjoins the first-planar area at a first end of first-planar area. The third-planar area has a third width greater than the minimum width 180. The third-planar area adjoins the first-planar area at a second end of first-planar area.
In another implementation of this embodiment, the processes at block 1402 and 1404 are performed as follows. A first-planar area is machined in a first section 361 of the first region parallel to the axial direction for an extent equal to a cavity length 140. A second-planar area is machined in a second section 362 of the first shallow-cavity 162. A third-planar area is machined in a third section 363 of the first shallow-cavity 162. The second-planar area has a second length perpendicular to the axial direction. The second-planar area is offset in a negative radial direction from the first-planar area. The third-planar area has a third length perpendicular to the axial direction. The third planar area is offset in a negative radial direction from the first-planar area.
In yet another implementation of this embodiment, first and second rectangular planar surfaces are machined in opposing first and second sections to have a length larger than the length of the dielectric bars. In one embodiment of this case, the vertical-corner edges of the dielectric bars that are parallel to the radial direction of the cylindrical piece, when installed, are chamfered. In another embodiment of this case, dielectric bar has chamfered corners at the edges of the flat-first surface that are perpendicular to the dielectric bar length. In yet another embodiment of this case, the dielectric bars have chamfered vertical-corner edges and chamfered corners at the edges of the flat-first surface that are perpendicular to the dielectric bar length.
Block 1406 is optional. At block 1406, a metal ring 190 is positioned over the outer surface 230 of the cylindrical tube. The metal ring 190 is offset, along the Z axis, from the first shallow-cavity 162 and the second shallow-cavity 162. In one implementation of this embodiment, the metal ring 190 is formed by machining the outer surface 131 of the inner-conductive tube 130. In another implementation of this embodiment, the metal ring 190 is formed as a separate piece from the inner-conductive tube 130 and is then positioned on the outer surface 131 of the inner-conductive tube 130.
At block 1408, a flat surface of a first dielectric bar is attached to the at least one planar area of the first shallow-cavity. In one implementation of this embodiment, the flat surface of a first dielectric 160-1 is positioned inside the first shallow-cavity 162-1 and then the flat surface of the first dielectric 160-1 is glued to the at least one planar area of the first shallow-cavity 162. In this manner, a flat-first surface of first dielectric 160-1 is parallel to and attached to a planar area in a first shallow-cavity 162-1 on the surface of the inner conductive tube 130.
At block 1410, a flat surface of a second dielectric bar is attached to the at least one planar area of the second shallow-cavity. In one implementation of this embodiment, the flat surface of a second dielectric 160-2 is positioned inside the second shallow-cavity 162 and the flat surface of the second dielectric 160-2 is glued to the at least one planar area of the second shallow-cavity 162. In this manner, a flat-first surface of second dielectric 160-2 is parallel to and attached to a planar area in a second shallow-cavity 162-2 on the surface of the inner conductive tube 130.
Thus, the various embodiments of the coaxial polarizers formed from the inner conductive tubes shown in
The coaxial polarizer 18 includes an outer-conductive tube 110 (of which only a portion is visible in
The inner-conductive tube 830 has an axial dimension parallel to a Z axis and an outer surface 930 (
As shown in
As shown in
The coaxial polarizer 18 can be arranged with reference to an input electromagnetic wave to output either right hand or left hand polarization as described above with reference to the coaxial polarizer 10. As is understandable to one skilled in the art, the various embodiments of shallow cavities on the outer surface of the inner-conductive tube and the various embodiments of dielectric bars can be used in any desired combination to provide many different configurations of the coaxial polarizers.
Example 1 includes a coaxial polarizer comprising: an outer-conductive tube; an inner-conductive tube positioned within the outer-conductive tube and axially aligned with the outer-conductive tube, the inner-conductive tube having two shallow-cavities on opposing portions of an outer surface of the inner-conductive tube, the shallow-cavities each having at least one planar area, the at least one planar area having a cavity length parallel to a Z axis and having at least one cavity width that is perpendicular to the Z axis and perpendicular to a radial direction of the inner-conductive tube, the at least one cavity width including a minimum width; and two dielectric bars each having a flat-first surface, the flat-first surface having a dielectric length parallel to the Z axis and a dielectric width perpendicular to the Z axis, the dielectric length being less than the cavity length and the dielectric width being less than the minimum width, wherein cross-sections of each of the two dielectric bars taken perpendicular to the Z axis have four respective surfaces in a rectangular shape, and wherein the two flat-first surfaces of the respective two dielectric bars contact at least a portion of the respective two planar areas of the two shallow-cavities.
Example 2 includes the coaxial polarizer of Example 1, further comprising: a metal ring encircling the outer surface of the inner-conductive tube, the ring being offset, along the Z axis, from the shallow-cavities.
Example 3 includes the coaxial polarizer of any of Examples 1-2, wherein the two opposing planar areas of the respective two shallow-cavities comprises: a first planar area in a first section having a first-cavity width equal to the minimum width, first-cavity width being perpendicular to the Z axis and perpendicular to a radial direction of the inner-conductive tube; a second planar area in a second section adjoined to the first section and having a second-cavity width perpendicular to the Z axis and perpendicular to the radial direction of the inner-conductive tube; and a third planar area in a third section adjoined to the first section having a third-cavity width perpendicular to the Z axis and perpendicular to the radial direction of the inner-conductive tube, wherein the second section and the third section are offset from each other by a length of the first section, and wherein the second-cavity width and the third-cavity width are larger than the minimum width.
Example 4 includes the coaxial polarizer of Example 3, wherein the at least one planar area of at least one of the opposing two shallow-cavities comprises: a first-planar area that spans a first plane in the first section; a second-planar area that spans a second plane in the second section, the second plane being offset in a negative radial direction from the first plane; and a third planar area that spans a third plane in the third section, the third plane being offset in the negative radial direction from the first plane.
Example 5 includes the coaxial polarizer of any of Examples 1-4, wherein at least one of the two dielectric bars has at least one chamfered corner at at least one of the edges of the flat-first surface perpendicular to the dielectric length.
Example 6 includes the coaxial polarizer of any of Examples 1-5, wherein the at least one planar area of the respective two shallow-cavities include a single planar area that is rectangular in shape.
Example 7 includes the coaxial polarizer of Example 6, wherein the rectangular shape of the at least one planar area includes rounded corners, wherein each of the two dielectric bars further comprises: at least one chamfered-edge perpendicular to the flat-first surface, wherein at least one chamfered-edge is proximal to a respective at least one rounded corner when the flat-first surface of the dielectric bar contacts the at least a portion of the planar area of the shallow-cavity.
Example 8 includes the coaxial polarizer of any of Examples 1-7, wherein the cross-sections of each of the two dielectric bars taken perpendicular to the Z axis include: a first-cross-section having a first-rectangular shape including a width that is less than the minimum width, and wherein a second-cross-section having a second-rectangular shape including a width that is less than the minimum width.
Example 9 includes an inner-conductive tube for use in a coaxial polarizer, comprising: a first shallow-cavity on an outer surface of the inner-conductive tube, wherein the first shallow-cavity has a first-full-planar area, the first-planar area having a first-cavity length parallel to a Z axis and having at least one first-cavity width perpendicular to the Z axis and perpendicular to a first radial direction of the inner-conductive tube, the at least one first-cavity width including a first-minimum width; and a second shallow-cavity on the outer surface of the inner-conductive tube, the second shallow-cavity opposing the first shallow-cavity and having a second-full-planar area, the second-full-planar area having a second-cavity length parallel to the Z axis and having at least one second-cavity width perpendicular to the Z axis and perpendicular to a second radial direction of the inner-conductive tube, the at least one second-cavity width including a second-minimum width.
Example 10 includes the inner-conductive tube of Example 9, further comprising: a metal ring encircling the outer surface of the inner-conductive tube, the ring being offset, along the Z axis, from the first shallow-cavity and the second shallow-cavity.
Example 11 includes the inner-conductive tube of any of Examples 9-10, wherein the first-cavity length equals the second-cavity length and the at least one first-cavity width equals the at least one second-cavity width.
Example 12 includes the inner-conductive tube of any of Examples 9-11, wherein the first-full-planar area of the first shallow-cavity comprises: a first planar area in a first section having a first-cavity width equal to the first-minimum width, and first-cavity width being perpendicular to the Z axis and perpendicular to the first radial direction of the inner-conductive tube; a second planar area in a second section adjoined to the first section and having a second-cavity width perpendicular to the Z axis and perpendicular to the first radial direction of the inner-conductive tube; and a third planar area in a third section adjoined to the first section having a third-cavity width perpendicular to the Z axis and perpendicular to the first radial direction of the inner-conductive tube, wherein the second section and the third section are offset from each other by a length of the first section, and wherein the second-cavity width and third-cavity width are larger than the first-minimum width.
Example 13 includes the inner-conductive tube of Example 12, wherein the second-full-planar area of the second shallow-cavity comprises: a fourth planar area in a fourth section having the fourth-cavity width equal to the second-minimum width, the fourth-cavity width being perpendicular to the Z axis and perpendicular to the second radial direction of the inner-conductive tube; a fifth planar area in a fifth section adjoined to the fourth section having a fifth-cavity width perpendicular to the Z axis and perpendicular to the second radial direction of the inner-conductive tube; and a sixth planar area in a sixth section adjoined to the fourth section having a sixth cavity width perpendicular to the Z axis, wherein the fifth section and the sixth section are offset from each other by a length of the fourth section, and wherein the fifth-cavity width and sixth-cavity width are larger than the second-minimum width.
Example 14 includes the inner-conductive tube of any of Examples 9-13, wherein at least one of the first shallow-cavity and the second shallow-cavity comprises: a first-section-planar area that spans a first plane, the first-section-planar area having the first-cavity width equal to the first-minimum width, the first-cavity width being perpendicular to the Z axis and perpendicular to the first radial direction of the inner-conductive tube; a second-section-planar area that spans a second plane adjoining the first plane, the second-section-planar area having a third-cavity width perpendicular to the Z axis and perpendicular to the first radial direction of the inner-conductive tube, the second plane being offset in a negative radial direction from the first plane; and a third-section-planar area that spans a third plane adjoining the first plane, the third-section-planar area having a fourth-cavity width perpendicular to the Z axis and perpendicular to the first radial direction of the inner-conductive tube, the third plane being offset in the negative radial direction from the first plane, wherein the second-section-planar area and the third-section-planar area are offset from each other by a length of the first-section-planar area, and wherein the third-cavity width and the fourth-cavity width are larger than the first-minimum width.
Example 15 includes the inner-conductive tube of any of Examples 9-14, wherein at least one of the first-full-planar area of the first shallow-cavity and the second-full-planar area of the second shallow-cavity is rectangular in shape.
Example 16 includes a method of making an inner-conductive tube, the method comprising: machining a first shallow-cavity having at least one first-planar area on an outer-curved surface of a cylindrical piece aligned to an axial direction; and machining a second shallow-cavity having at least one second-planar area on an outer-curved surface of the cylindrical piece, wherein the first-planar area opposes the second planar area.
Example 17 includes the method of Example 16, wherein machining the first shallow-cavity having the at least one first-planar area on the first region of the outer surface of the cylindrical tube comprises: machining a first-planar area in a first section of the first shallow-cavity, the first-planar area having a length parallel to the axial direction and a first width perpendicular to the axial direction; machining a second-planar area in a second section of the first shallow-cavity, the second-planar area having a second width perpendicular to the axial direction and the second-planar area adjoining the first-planar area at a first end of first-planar area; and machining a third-planar area in a third section of the first shallow-cavity, the third-planar area having a third width perpendicular to the axial direction and the third-planar area adjoining the first-planar area at a second end of first-planar area.
Example 18 includes the method of any of Examples 16-17, wherein machining the first shallow-cavity having the at least one first-planar area on the first region of the outer surface of the cylindrical tube comprises: machining a first-planar area in a first section of the first, the first-planar area having a length parallel to the axial direction and a first width perpendicular to the axial direction; machining a second-planar area in a second section of the first shallow-cavity, the second-planar area having a second width perpendicular to the axial direction, wherein second-planar area is offset in a negative radial direction from the first-planar area; and machining a third-planar area in a third section of the first shallow-cavity, third-planar area having a third width perpendicular to the axial direction, wherein the third planar area is offset in a negative radial direction from the first-planar area.
Example 19 includes the method of any of Examples 16-18, further comprising: positioning a metal ring over the outer surface of the cylindrical tube, wherein the ring is offset, along the Z axis, from the first shallow-cavity and the second shallow-cavity.
Example 20 includes the method of any of Examples 16-19, further comprising: attaching a flat surface of a first dielectric bar to the at least one planar area of the first shallow-cavity; and attaching a flat surface of a second dielectric bar to the at least one planar area of the second shallow-cavity.
A number of embodiments of the invention defined by the following claims have been described. Nevertheless, it will be understood that various modifications to the described embodiments may be made without departing from the spirit and scope of the claimed invention. For example, although the technique for machining an inner-conductive core of a coaxial polarizer is described above, the technique for forming the shallow cavities on the outer surface of the inner-conductive core can include other processes including heating the metal and impressing the shallow cavities on the outer surface of the inner-conductive core or other types of molding or shaping metal. Accordingly, other embodiments are within the scope of the following claims.
The U.S. Government may have rights in the invention under Government Contract No. H94003-04-D-0005/7600009933 awarded by the U.S. Government to Northrop Grumman and under Government Contract No. F33657-02-D-0009/4743848 awarded by the U.S. Government to Lockheed Martin.
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