Differential partitioned aperture
The RF aperture design with conductive tapered projections and integrated chip baluns on multiple circuit boards addresses the challenge of broadband RF capture and compactness, facilitating efficient RF transmission and reception in mobile platforms.
Patent Information
- Authority / Receiving Office
- JP · JP
- Patent Type
- Applications
- Current Assignee / Owner
- BATTELLE MEMORIAL INST
- Filing Date
- 2026-04-20
- Publication Date
- 2026-07-02
AI Technical Summary
Existing RF apertures face challenges in efficiently capturing a broad range of RF wavelengths and require compact, lightweight designs suitable for applications in mobile platforms.
The implementation of an RF aperture with an interface printed circuit board featuring conductive tapered projections and chip baluns, along with an RF network, allows for differential RF signal capture and beam steering, utilizing a phased array configuration with integrated electronic components on multiple circuit boards.
This design achieves broadband RF capture and compact, lightweight RF apertures suitable for mobile platforms, enabling flexible RF transmission and reception with reduced radar cross-section and enhanced signal processing capabilities.
Smart Images

Figure 2026110677000001_ABST
Abstract
Description
Technical Field
[0001] This application claims the benefit of U.S. Provisional Application No. 62 / 839,121, filed on April 26, 2019, and titled "DIFFERENTIAL SEGMENTED APERTURE". U.S. Provisional Application No. 62 / 839,121, filed on April 26, 2019, is hereby incorporated by reference in its entirety.
[0002] (Background) The following relates to the fields of radio frequency (RF) technology, RF transmitter technology, RF receiver technology, RF transceiver technology, broadband RF transmitter, receiver, and / or transceiver technology, RF communication technology, and related technology fields.
[0003] Steinbrecher's U.S. Patent No. 7,420,522, titled "Electromagnetic Radiation Interface System and Method", discloses a broadband RF aperture as follows: "An electromagnetic radiation interface suitable for use in combination with radio frequencies is provided. The surface comprises a plurality of metallic conical bristles. A corresponding plurality of termination segments are provided such that each bristle is terminated with an associated termination segment. The termination segments may capture substantially all of the electromagnetic wave energy received by each individual bristle and thereby have an electrical resistance to prevent reflection from the surface of the interface. Each termination segment may also include an analog / digital converter for converting the energy from each bristle into a digital word. The bristles may be mounted on a ground plane having a plurality of holes therethrough. A plurality of coaxial transmission lines may extend through the ground plane for interconnecting the plurality of bristles to the plurality of termination segments."
[0004] Some improvements are disclosed herein.
Prior Art Documents
Patent Documents
[0005] [Patent Document 1] U.S. Publication No. 7,420,522 [Overview of the Initiative] [Means for solving the problem]
[0006] (Brief summary) According to several illustrative embodiments, radio frequency (RF) apertures are disclosed. An interface printed circuit board has a front side and a back side. An array of conductive tapered projections has a base located on the front side of the interface printed circuit board and extends away from the front side of the interface printed circuit board. Chip baluns are mounted on the back side of the interface printed circuit board. Each chip balun has a balanced port that is electrically connected to two neighboring conductive tapered projections of the array of conductive tapered projections via an electrical feedthrough that passes through the interface printed circuit board. Each chip balun further has an unbalanced port. An RF network is located on the back side of the interface printed circuit board and is electrically connected to the unbalanced ports of the chip baluns.
[0007] According to some illustrative embodiments disclosed herein, a method for manufacturing a radio frequency (RF) aperture includes coating the surface of a dielectric tapered projection with a conductive layer to form a conductive tapered projection; mounting the conductive tapered projection on the front side of an interface printed circuit board; mounting an RF network on the interface printed circuit board and / or a second printed circuit board mounted parallel to the interface printed circuit; and electrically connecting the RF network to the conductive tapered projection.
[0008] According to some illustrative embodiments disclosed herein, the RF opening comprises an interface printed circuit board having a front side and a back side, an array of conductive tapered projections, and an RF network. The conductive tapered projections have a base located on the front side of the interface printed circuit board and extend away from the front side of the interface printed circuit board. The conductive tapered projections comprise a dielectric tapered projection and a conductive layer located on the surface of the dielectric tapered projection. The RF network is located on the back side of the interface printed circuit board and is electrically connected to the array of conductive tapered projections via an electrical feedthrough passing through the interface printed circuit board. In some embodiments, the RF network further includes a balun with a balanced port that connects pairs of adjacent conductive tapered projections within the array of conductive tapered projections via an electrical feedthrough passing through the interface printed circuit board. This specification also provides, for example, the following items: (Item 1) Radio frequency (RF) aperture, An interface printed circuit board having a front side and a back side, An array of conductive tapered protrusions having a base positioned on the front side of the interface printed circuit board and extending away from the front side of the interface printed circuit board, A balun mounted on the back side of the interface printed circuit board, wherein each balun has a balanced port electrically connected to two neighboring conductive tapered protrusions of the array of conductive tapered protrusions via an electrical feedthrough passing through the interface printed circuit board, and each balun further has an unbalanced port, An RF network is located on the back side of the interface printed circuit board and is electrically connected to the unbalanced port of the balun. An RF aperture equipped with this. (Item 2) The RF aperture according to item 1, wherein the balun comprises a chip balun, and the RF network comprises electronic components mounted on the back side of the interface printed circuit board. (Item 3) The system further comprises a second printed circuit board, which is arranged parallel to the interface printed circuit board and faces the back side of the interface printed circuit board. The RF network comprises an RF aperture according to any one of items 1-2, mounted on the second printed circuit board, and includes electronic components. (Item 4) The RF network comprises an RF power divider / coupler connecting one or more combinations of the balun's unbalanced ports to one or more RF connectors, as described in any one of items 1-3, for the RF aperture. (Item 5) The RF power divider / coupler is interconnected as a plurality of RF subassemblies, each RF subassembly connecting four or more subassemblies of the balun's unbalanced ports to a single RF connector, as described in item 4. (Item 6) The RF network further includes multiple analog-to-digital (A / D) converters, The RF power divider / coupler is interconnected as a plurality of RF subassemblies, each RF subassembly connecting four or more subassemblies of the balun's unbalanced ports to a single analog-to-digital (A / D) converter, as described in item 4. (Item 7) The RF network comprises signal conditioning circuits connected to each unbalanced port of the balun, and the signal conditioning circuits connected to each unbalanced port are RF transmission amplifier, RF receiver amplifier, An RF switching network configured to switch between a transmission mode in which the RF transmission amplifier is operably connected to the unbalanced port and a reception mode in which the RF reception amplifier is operably connected to the unbalanced port. An RF aperture as described in any one of items 1-6, including the one described in item 1-6. (Item 8) The RF circuit network includes a beam steering circuit network configured to operate the RF aperture as a phased array directional RF transmitter and / or a phased array directional RF receiver, the RF aperture according to any one of items 1-7. (Item 9) The array of conductive tapered protrusions includes a dielectric tapered protrusion and a conductive layer disposed on the surface of the dielectric tapered protrusion, the RF aperture according to any one of items 1-8. (Item 10) The RF aperture according to item 9, comprising a dielectric plate including the dielectric tapered protrusion. (Item 11) The dielectric tapered protrusion is hollow, and the conductive layer is disposed on the outer surface or the inner surface of the hollow dielectric tapered protrusion, the RF aperture according to any one of items 9-10. (Item 12) A method of manufacturing a radio frequency (RF) aperture, comprising: coating the surface of a dielectric tapered protrusion with a conductive layer to form a conductive tapered protrusion; mounting the conductive tapered protrusion on the front side of an interface printed circuit board; mounting an RF circuit network on the interface printed circuit board and / or on a second printed circuit board mounted in parallel with the interface printed circuit; electrically connecting the RF circuit network to the conductive tapered protrusion and. (Item 13) The dielectric tapered protrusion is integral with the surface of a dielectric plate and extends away from the surface of the dielectric plate, and the coating includes coating the dielectric plate including at least the integral dielectric tapered protrusion, and the method further includes After said coating, etching the coating away from the plate between the conductive tapered protrusions to electrically isolate the conductive tapered protrusions from each other DC, or Before said coating, depositing a mask material on the plate between the conductive tapered protrusions such that the coating does not coat the plate between the conductive tapered protrusions, whereby the conductive tapered protrusions are electrically isolated from each other DC The method according to claim 12, comprising one of the above. (Item 14) Mounting the RF circuit network includes mounting a balun on the back side of the interface printed circuit board, Said electrically connecting includes electrically connecting each balanced port of the balun to two of the conductive tapered protrusions via an electrical feed-through passing through the interface printed circuit board. The method according to any one of claims 12-13. (Item 15) A radio frequency (RF) aperture, An interface printed circuit board having a front side and a back side, An array of conductive tapered protrusions having a base disposed on the front side of the interface printed circuit board and extending away from the front side of the interface printed circuit board, the conductive tapered protrusions comprising a dielectric tapered protrusion and a conductive layer disposed on the surface of the dielectric tapered protrusion. An array of conductive tapered protrusions, An RF circuit network disposed on the back side of the interface printed circuit board and electrically connected to the array of conductive tapered protrusions via an electrical feed-through passing through the interface printed circuit board An RF aperture comprising. (Item 16) The RF opening according to item 15, comprising a dielectric plate including the dielectric tapered projections, wherein the conductive layer is not a coating on the plate between the dielectric tapered projections, such that the dielectric tapered projections are DC-insulated from each other. (Item 17) The dielectric tapered projection is hollow, as described in any one of items 15-16, for the RF opening. (Item 18) The RF network comprises an RF aperture according to any one of items 15-17, which is mounted on the back side of the interface printed circuit board. (Item 19) The system further comprises a second printed circuit board, which is arranged parallel to the interface printed circuit board and faces the back side of the interface printed circuit board. The RF network comprises an RF aperture according to any one of items 15-18, which is mounted on the second printed circuit board and includes electronic components. (Item 20) The RF aperture according to any one of items 15-19, wherein the RF network includes a balun with a balanced port connecting adjacent pairs of conductive tapered projections within the array of conductive tapered projections via the electrical feedthrough passing through the interface printed circuit board. (Item 21) The RF network further includes an RF aperture as described in item 20, each including a first-level RF power divider / coupler, each connecting the unbalanced ports of two baluns. (Item 22) The RF network further includes a second-level RF power divider / coupler, each connecting two first-level RF power dividers / couplers, as described in item 21. (Item 23) The RF network further includes signal conditioning circuits connected to the unbalanced ports of each balun, and the signal conditioning circuits are RF transmission amplifier, RF receiver amplifier, An RF switching network configured to switch between a transmission mode in which the RF transmission amplifier is operably connected to the unbalanced port and a reception mode in which the RF reception amplifier is operably connected to the unbalanced port. RF apertures as described in any one of items 20-22, including those specified in item 20-22. (Item 24) The RF aperture according to any one of items 15-23, wherein the RF network includes a beam steering network configured to cause the RF aperture to operate as a phased array directional RF transmitter and / or phased array directional RF receiver. [Brief explanation of the drawing]
[0009] Any quantitative dimensions shown in the drawings shall be understood as non-limiting illustrative examples. Unless otherwise indicated, the drawings are shown as if any aspect of the drawings were at an exact scale, rather than at an exact scale, and the scales shown shall be understood as non-limiting illustrative examples.
[0010] [Figure 1] Figures 1 and 2 schematically illustrate the front and side cross-sectional views, respectively, of an illustrative differential compartmentalization aperture (DSA). [Figure 2] Figures 1 and 2 schematically illustrate the front and side cross-sectional views, respectively, of an illustrative differential compartmentalization aperture (DSA).
[0011] [Figure 3] Figure 3 schematically shows a block diagram of a single QUAD subassembly of the DSA shown in Figures 1-4.
[0012] [Figure 4] Figure 4 schematically illustrates the front view of the DSA interface printed circuit board (i-PCB) shown in Figures 1-3, including vias and mounting holes, and schematically shows the locations of the balun and register pads.
[0013] [Figure 5]Figure 5 schematically illustrates the rear view of the DSA enclosure shown in Figure 1-4, including the graphically indicated RF connection, control unit, and power connector.
[0014] [Figure 6] Figure 6 schematically illustrates the connection of the balanced port of the chip balun between two adjacent conductive tapered projections, as well as a schematic side cross-sectional view of an embodiment with conductive tapered projections.
[0015] [Figure 7] Figure 7-10 schematically illustrates an additional embodiment of the conductive tapered projection. [Figure 8] Figure 7-10 schematically illustrates an additional embodiment of the conductive tapered projection. [Figure 9] Figure 7-10 schematically illustrates an additional embodiment of the conductive tapered projection. [Figure 10] Figure 7-10 schematically illustrates an additional embodiment of the conductive tapered projection. [Modes for carrying out the invention]
[0016] (Detailed explanation) Referring to Figures 1 and 2, an illustrative front and side section view of an RF aperture is shown, which includes an interface printed circuit board (i-PCB) 10 having a front side 12 and a back side 14, and an array of conductive tapered projections 20 having a base 22 positioned on the front side 12 of the i-PCB 10 and extending away from the front side 12 of the i-PCB 10. The illustrative i-PCB 10 is shown in Figure 1 as having dimensions of 5 inches x 5 inches, but this is only a non-limiting illustrative embodiment of a small RF aperture. Figure 1 shows a front view of the RF aperture, accompanied in the upper left by an inset showing a perspective view of one conductive tapered projection 20. This illustrative embodiment of the conductive tapered projection 20 has a square cross-section with a larger square base 22 and a vertex that does not extend to a full tip but rather terminates at a flat vertex 24 (in other words, the conductive tapered projection 20 in the inset has a frustoconical shape). This is merely an illustrative example, and more generally, the conductive tapered projection 20 can have any type of cross-section (e.g., square as in the inset, or circular, or hexagonal, or octagonal, etc.). The vertex 24 can be flat as in the embodiment of the inset, or it can reach an acute point, or it can be rounded, or it can have some other vertex geometric shape. The tapering rate as a function of height (i.e., the distance "above" the base 22 when the vertex 24 is at its maximum "height") can be constant, as in the embodiment of the inset, or the tapering rate can be variable with height. For example, the tapering rate can increase with increasing height to form a projection with a rounded apex, or decrease with increasing height to form a projection with a more pointed tip. Similarly, as shown in most detail in Figure 1, the illustrative array of conductive tapered projections 20 is a linear array with regular rows and orthogonal regular columns; however, the array may have other symmetries, such as hexagonal symmetry, octagonal symmetry, etc.In the illustrative embodiment shown in the inset, the square base 22 and square vertex 24 lead to a conductive tapered projection 20 having four flat, inclined side walls 26. However, other side wall shapes are also conceivable. For example, if the base and vertex are circular (or if the base is circular and the vertex reaches a certain point), the side walls may be inclined or tapered cylinders, with six inclined side walls in relation to the hexagonal base and hexagonal or pointed vertex.
[0017] Continuing with reference to Figures 1 and 2, and further with reference to Figure 3, the RF aperture further comprises an RF network including, in an illustrative embodiment, a chip balun 30 mounted on the back side 14 of the i-PCB 10. Each chip balun 30 is electrically connected to two neighboring conductive tapered projections of an array of conductive tapered projections via an electrical feedthrough 32 that passes through the i-PCB 10, through a balanced port P B Each chip balun 30 also has an unbalanced port P that connects to the rest of the RF network. U (See Figures 3 and 6). The illustrative RF network further includes the unbalanced port P of the chip balun 30. U It includes an RF power divider / coupler 40 for coupling the outputs from. As seen in Figure 3, the illustrative electrical configuration of the RF network is an unbalanced port P U A first-level 1x2 RF power divider / coupler 401 combines the pairs of power dividers and couplers, and a second-level 1x2 RF power divider / coupler 402 combines the outputs of the pairs of first-level RF power dividers / couplers 401. This is merely an illustrative approach, and other configurations are possible, such as using 1x3 (combining 3 lines), 1x4 (combining 4 lines), or higher-level coupled RF power dividers / couplers, or various combinations thereof. The illustrative RF network further includes each unbalanced port P of the chip balun 30. UThe signal conditioning circuit 42 is inserted between the first level 1x2 power divider 401 and the signal conditioning circuit 42 connected to each unbalanced port and includes an RF transmission amplifier T, an RF reception amplifier R, and an RF switching network including a switch RFS configured to switch between a transmission mode in which the RF transmission amplifier T and the unbalanced port are operably connected and a reception mode in which the RF reception amplifier R and the unbalanced port are operably connected.
[0018] Continuing with reference to Figures 1-3, and further with reference to Figures 4 and 5, a compact design (e.g., a depth of 3 inches in the non-limiting illustrative embodiment of Figure 3) is achieved, in part, by employing one or more printed circuit boards (PCBs) including at least an i-PCB 10. In the illustrative embodiment shown in Figure 3, a chip balun 30 is mounted on the back side 14 of the i-PCB 10. Optionally, other electronic components may also be mounted on the back side of the i-PCB 10, with an array of conductive tapered projections 20 on its front side 12. However, there may be insufficient occupied area on the i-PCB 10 to mount all the electronic components of the RF network. In the illustrative embodiment, this is addressed by providing a second printed circuit board 50 positioned in parallel with the i-PCB 10 and facing the back side 14 of the i-PCB 10. In other words, the second printed circuit board 50 is located on the (back) side 14 of the i-PCB 10 opposite to the (front) side 12 where the conductive tapered projections 20 are located. The RF network comprises electronic components mounted on the second printed circuit board 50, which may also be referred to herein as a signal conditioning PCB or SC-PCB 50, and additionally, or alternatively, electronic components mounted on the i-PCB 10 (typically on the back side 14 of the i-PCB, but it is also conceivable that the RF network components be mounted on the front side of the i-PCB in the field space between the conductive tapered projections 20 (not shown)). If the SC-PCB 50 is provided, as shown in Figure 2, it is appropriately fixed parallel to the i-PCB 10 by standoffs 54, and a single-ended feedthrough 52 is provided for electrically interconnecting the i-PCB 10 and the SC-PCB 50 (see Figure 3). If the RF network cannot be fitted onto the occupied area of the two PCBs 10, 50, a third (and optionally a fourth, and further) PCB may be added to accommodate the components of the RF network (not shown).
[0019] Figure 4 shows a front view of the i-PCB10, including vias and mounting holes, and schematically illustrates the locations of the balun 30 and register pads as shown in the legend in Figure 4. (The registers are used to terminate the unused side of the pyramid to help reduce the radar cross-section.)
[0020] Referring to Figure 2, and further to Figure 5, the illustrative RF opening has an enclosure 58 fixed around the periphery of the i-PCB 10 such that the periphery of the i-PCB 10 encloses the RF network. This is only one illustrative arrangement, and other designs are conceivable, for example, both PCBs 10 and 50 may be located inside the enclosure (however, such an enclosure should not include an RF shielding extending forward to block the area of the RF opening). Figure 5 schematically illustrates the rear view of an RF aperture enclosure 58, showing a schematicly represented RF connector (or port) 60 (also shown or displayed in Figures 2 and 3), control electronics 62 (e.g., illustrative phased array beam steering electronics 63, shown as a non-limiting figure, which may be mounted outside the enclosure 58 and / or located inside the enclosure 58 to provide useful RF shielding), and a power connector 64 for providing power to operate the active components of the RF network (e.g., operating power for an active RF transmission amplifier T, an active RF reception amplifier R, and a switch RFS). The specific arrangement of the various components 60, 62, 63, 64 across the rear surface area of the enclosure can vary widely from that shown in Figure 5, and these components may be located elsewhere, for example, the RF connector 60 may be located alternatively at the edge of the RF aperture. It should also be understood that if the RF aperture is constructed in conjunction with some other component or system, for example, if the RF aperture is used as an RF transmission element and / or receiving element in a mobile ground station, maritime radio, or unmanned aerial vehicle (UAV), the enclosure 58 may be replaced by having an RF aperture built into the housing of the mobile ground station, maritime radio, UAV airframe, etc. In such cases, the RF connector 60 may also be replaced by a wired connection to the mobile ground station, maritime radio, UAV electronics, etc.
[0021] Referring particularly to Figure 3, an illustrative electrical configuration for an illustrative RF network is shown. In this non-limiting illustrative embodiment, the array of conductive tapered projections 20 is assumed to be a 5 × 5 array of conductive tapered projections 20, as shown in Figures 1 and 4. The balanced port P of the tip balun 30 BThe array connects adjacent (i.e., neighboring) pairs of conductive tapered projections 20 to receive a differential RF signal between two adjacent conductive tapered projections 20 (in receiving mode, or alternatively, in transmission mode, to apply a differential RF signal between two adjacent conductive tapered projections 20). As detailed in Steinbrecher's U.S. Patent No. 7,420,522 (which is incorporated herein by reference as a whole), the tapering of the conductive tapered projections 20 presents separation between two conductive tapered projections 20, which varies with "height," i.e., with respect to the distance "above" the base 22 of the conductive tapered projections 20. This provides broadband RF capture, as a range of RF wavelengths corresponding to the range of separation between adjacent conductive tapered projections 20 introduced by the tapering can be captured. The RF aperture is therefore a differential compartmentalized aperture (DSA) and has differential RF receiving (or RF transmitting) elements corresponding to adjacent pairs of conductive tapered projections 20. These differential RF receiving (or transmitting) elements are referred to herein as aperture pixels. With respect to an illustrative linear 5×5 array of adjacent conductive tapered projections 20, this means that there are four aperture pixels along each row (or column) of five conductive tapered projections 20. More generally, with respect to a linear array of projections having N rows (or columns) of conductive tapered projections 20, there will be N-1 corresponding pixels along the row (or column). Figure 3 shows a QUAD subassembly, which is an interconnection of rows (or columns) of four pixels. Since there are four rows and four columns, this leads to 4×4 or 16 such QUAD subassemblies. Register pads are used as terminations for the unused edges of the surrounding pyramids to prevent unwanted reflections. Without the resistors mounted via the resistor pads, their surfaces would remain floating, re-radiating incident RF energy and potentially causing an enhanced radar cross-section.
[0022] In the illustrative embodiment shown in Figure 3, the second-level 1×2 RF power divider / coupler 402 of each QUAD subassembly connects to the RF connector 60 on the rear side of the enclosure 58. Thus, as seen in Figure 5, there are eight RF connectors for the eight QUAD subassemblies shown in Figures 4 and 5, such as row QUAD subassemblies N1, N2, N3, N4 and column QUAD subassemblies M1, M2, M3, M4. The Gnd(N) row and Gnd(M) column are circuit grounds to allow a common path for current flow from captured RF energy along the periphery of the pyramid. The use of QUAD subassemblies allows for a high level of flexibility in RF coupling to the RF aperture. For example, the illustrative phased array beam steering electronics 63 provides appropriate phase shifts for row QUAD subassemblies N1, N2, N3, N4.
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[0023] The electronic device described employing PCBs 10, 50, a chip balun 30, and active signal conditioning components (e.g., an active transmission amplifier T and a receiving amplifier R) advantageously allows the RF aperture to be fabricated in a small and lightweight form. As described below, embodiments of the conductive tapered projection 20 further facilitate the provision of a small and lightweight broadband RF aperture.
[0024] Figure 6 shows a side cross-sectional view of one illustrative embodiment in which each conductive tapered projection 20 is fabricated as a dielectric tapered projection 70 with a conductive layer 72 disposed on the surface of the dielectric tapered projection 70. The dielectric tapered projection may consist of an electrically insulating plastic or ceramic material such as acrylonitrile butadiene styrene (ABS), polycarbonate, etc., and may be manufactured by injection molding, three-dimensional (3D) printing, or other suitable techniques. The conductive layer 72 may be any suitable conductive material such as copper, copper alloys, silver, silver alloys, gold, gold alloys, aluminum, aluminum alloys, or may consist of a layered stack of different conductive materials, and may be coated onto the dielectric tapered projection 70 by vacuum evaporation, RF sputtering, or any other vacuum deposition technique. Figure 6 shows one embodiment in which a soldering point 74 is used to electrically connect the conductive layer 72 of each dielectric tapered projection 20 to its corresponding electrical feedthrough 32 passing through the i-PCB 10. Figure 6 also shows the balancing port P of one tip balun 30 between two adjacent conductive tapered projections 20 via a soldering point 76. B The illustrative connection is also shown.
[0025] Figures 7 and 8 show an exploded side section and perspective view, respectively, of one embodiment in which dielectric tapered projections 70 are integrally contained within a dielectric plate 80. The conductive layer 72 coats each dielectric tapered projection 70 but has insulating gaps 82 that provide galvanic insulation between neighboring dielectric tapered projections 20. The insulating gaps 82 can be formed after coating the conductive layer 72 by etching the coating away from the plate 80 between the conductive tapered projections 20, thereby DC-insulating the conductive tapered projections from each other. Alternatively, the insulating gaps 82 can be defined before coating by depositing a mask material (not shown) on the plate 80 between the conductive tapered projections 20 so that the coating does not coat the plate within the insulating gaps 82 between the conductive tapered projections, thereby DC-insulating the conductive tapered projections from each other. As can be seen in the perspective view of Figure 8, the dielectric plate 80 consequently covers (and thus closes) the surface of the i-PCB 10, with the conductive tapered projection 20 extending away from the dielectric plate 80.
[0026] Referring particularly to Figure 7, in one approach for electrical interconnection, a through-hole 82 passes through the illustrative plate 80 and the underlying i-PCB 10, and a rivet, screw, or other conductive fastener 32' passes through the through-hole 82 (note that Figure 7 is an exploded view) and, therefore, when installed, forms an electrical feedthrough 32' that passes through the i-PCB 10. (Note that the perspective view in Figure 8 is simplified and does not depict the fastener 32'.) The use of the dielectric plate 80 with an integrated dielectric tapered projection 70 and combined fastener / feedthrough 32' advantageously allows the conductive tapered projection 20 to be installed without soldering using precise positioning.
[0027] In the embodiment shown in Figure 6-8, the conductive coating 72 is placed on the outer surface of the dielectric tapered projection 70. In this case, the dielectric tapered projection 70 may be hollow or solid.
[0028] Referring to Figures 9 and 10, since the dielectric material is substantially transparent to RF radiation, the conductive coating 72 may instead be coated on the inner surface of the (hollow) dielectric tapered projection 70. Figure 9 shows a side section view of such an embodiment, while Figure 10 shows a perspective view. The embodiments of Figures 9 and 10 again employ a dielectric plate 80 including the dielectric tapered projection 70. As seen in Figure 10, coating the inner surface of the hollow dielectric tapered projection 70 with the conductive coating 72 protects the conductive coating 72 from external contact by the dielectric plate 80 including the integrated dielectric tapered projection 70. This may be useful in environments where weather may be a concern.
[0029] It should be understood that various aspects disclosed are illustrative examples, and that disclosed features may be combined or omitted in various ways in specific embodiments. For example, one of the illustrative examples of the conductive tapered projection 20 or a variation thereof may be adopted without the QUAD subassembly network configuration shown in Figure 2-5. Conversely, the QUAD subassembly network configuration shown in Figure 2-5 or a variation thereof may be adopted without the dielectric / coating configuration for the conductive tapered projection 20. Similarly, the chip balun 30 may or may not be used in specific embodiments.
[0030] Preferred embodiments are illustrated and described. Naturally, modifications and alterations will be conceivable to those skilled in the art, provided they carefully read and understand the preceding detailed description. It is intended that the present invention includes all such modifications and alterations to the extent that they fall within the scope of the appended claims or their equivalents.
Claims
1. A radio frequency (RF) aperture, An interface printed circuit board having a front side and a back side, An array of conductive tapered protrusions, each conductive tapered protrusion having a base located on the front side of the interface printed circuit board and extending away from the front side of the interface printed circuit board to the apex, A balun mounted on the back of the interface printed circuit board, wherein each balun has a balanced port electrically connected to two neighboring conductive tapered protrusions via an electrical feedthrough passing through the interface printed circuit board to receive or apply a differential RF signal between two neighboring conductive tapered protrusions of a linear array of conductive tapered protrusions, and each balun further has an unbalanced port, An RF network is located on the back side of the interface printed circuit board and is electrically connected to the unbalanced port of the balun. An enclosure configured to enclose the aforementioned RF circuit network and An RF aperture equipped with this.
2. The RF opening according to claim 1, wherein the enclosure is fixed to the periphery of the interface printed circuit board.
3. Further comprising a second printed circuit board arranged parallel to the interface printed circuit board and facing the back side of the interface printed circuit board, The RF aperture according to any one of claims 1-2, wherein the RF network comprises electronic components mounted on the second printed circuit board.
4. The RF opening according to claim 3, wherein the interface printed circuit board and the second printed circuit board are arranged inside the enclosure.
5. The RF aperture according to any one of claims 1 to 4, wherein the RF network comprises electronic components mounted on the back side of the enclosure.
6. The RF aperture according to claim 5, wherein the electronic component includes at least one RF connector configured to connect to the unbalanced port of the balun.
7. The RF aperture according to any one of claims 5 or 6, wherein the electronic component includes a control electronic device.
8. The RF aperture according to claim 7, wherein the control electronic equipment includes a beam steering network configured to operate the RF aperture as a phased array directional RF transmitter and / or phased array directional RF receiver.
9. The RF aperture according to any one of claims 5-8, wherein the electronic component includes a power connector configured to supply power to the RF network.
10. The RF opening according to any one of claims 1 to 9, wherein the conductive tapered projection has four-fold rotational symmetry.
11. The RF opening according to any one of claims 1 to 9, wherein the conductive tapered projection is arranged on the front side of the interface printed circuit board in a linear array.