Abstract: A communications array includes a support structure configured to array elements, and a plurality of array elements supported by the support structure. Each array element is fabricated from an advanced manufacturing techniques (AMT) process. The support structure may be fabricated from a printed circuit board (PCB) or similar dielectric material. Each array element may include a radiator and/or a beamformer manufactured using the AMT process. The communications array further may include a copper vertical launch (CVL) and/or an electromagnetic boundary.

Abstract: A process of fabricating an electromagnetic circuit includes providing three laminate sheets, forming a first feature in a first laminate sheet of the three laminate sheets, and forming a second feature in a second laminate sheet of the three laminate sheets. The second feature is aligned with the first feature when aligning the second laminate sheet with the first laminate sheet. The process further includes stacking the three laminate sheets so that the first laminate sheet is positioned above and aligned with the second laminate sheet and the second laminate sheet is positioned above and aligned with the third laminate sheet. The first feature and the second feature define a contiguous element. The process further includes filling the contiguous element with an electrically conductive material to form an electrically continuous conductor.

Abstract: An apparatus to automatically place layers of a printed circuit board on a fixture includes a robotic device having a base that is secured to a surface, an upright column that extends upwardly from the base, and a movable arm rotatably coupled to the upright column. The movable arm is configured to rotate about a vertical axis defined by the upright column. The movable arm is further configured to rotate from a position in which the movable arm is disposed over a laminate sheet fixture and to pick up a laminate sheet to a position in which the movable arm is disposed over a board layup fixture to deposit the laminate sheet in the board layup fixture, and from a position in which the movable arm is disposed over a bond film fixture and to pick up a bond film to a position in which the movable arm is disposed over the board layup fixture to deposit the bond film in the board layup fixture.

Abstract: A radio frequency connector includes a substrate, a first ground plane disposed upon the substrate, a signal conductor having a first contact point, with the first contact point being configured to electrically mate with a second contact point, and a first ground boundary configured to electrically mate with a second ground boundary, with the first ground boundary being formed as an electrically continuous conductor within the substrate.

Abstract: An apparatus for automating the fabrication of a copper vertical launch (CVL) within a printed circuit board (PCB) includes a feed mechanism to feed and extrude copper wire from a spool of copper wire and a wire cutting and gripping mechanism to receive copper wire from the feed mechanism, cut and secure a segment of copper wire, insert the segment of copper wire into a hole formed within the PCB, solder an end of the segment of copper wire to a signal trace of the PCB, and flush cut an opposite end of the segment of the copper wire to a surface of the PCB. The wire cutting and gripping mechanism includes a wire cutter to flush cut the segment of copper wire and an integrated heated gripper device to receive the copper wire from the spool of copper wire and cut and grab a segment from copper wire.

Abstract: An array includes a support structure configured to support columns of beamformer assemblies, and a plurality of beamformer assemblies supported by the support structure. Each beamformer assembly includes at least one beamformer having at least one first beamformer segment and at least one second beamformer segment configured to interconnect with the first beamformer segment.

Abstract: A radio frequency connector includes a substrate, a first ground plane disposed upon the substrate, a signal conductor having a first contact point, with the first contact point being configured to electrically mate with a second contact point, and a first ground boundary configured to electrically mate with a second ground boundary, with the first ground boundary being formed as an electrically continuous conductor within the substrate.

Abstract: A method includes blending a dielectric material including a titanate with a carbon-based ink to form a modified carbon-based ink. The method also includes printing the modified carbon-based ink onto a structure. The method further includes curing the printed modified carbon-based ink on the structure at a temperature that does not exceed about 250° C. In addition, the method includes processing the cured printed modified carbon-based ink to form a thick film resistor. Blending the dielectric material with the carbon-based ink causes the modified carbon-based ink to have a resistivity that is at least double a resistivity of the carbon-based ink.

Abstract: A circuit structure includes a signal substrate having a signal trace formed thereon and a microstrip substrate disposed above the signal substrate that includes a microstrip trace formed thereon and a hole passing through it. The circuit structure also includes a conductor passing through and substantially filling the hole passing through the microstrip substrate and electrically contacting the signal trace on the signal substrate and a flat wire connector electrically connecting the microstrip trace to a first end of the conductor, the flat wire connector being arranged such that a gap is formed between the flat wire connector and a top surface of the microstrip substrate.

Abstract: A method includes blending a dielectric material including a titanate with a carbon-based ink to form a modified carbon-based ink. The method also includes printing the modified carbon-based ink onto a structure. The method further includes curing the printed modified carbon-based ink on the structure at a temperature that does not exceed about 250° C. In addition, the method includes processing the cured printed modified carbon-based ink to form a thick film resistor. An amount of the dielectric material blended with the carbon-based ink does not exceed about 15% by weight of the modified carbon-based ink. The modified carbon-based ink has a resistivity that is at least double a resistivity of the carbon-based ink. The thick film resistor may be configured to handle up to about 200 mA of current without fusing and/or handle up to about 1.0 W of power without fusing.

Abstract: A radio frequency circuit includes at least one dielectric substrate, a trench formed in the dielectric substrate, and an electrically continuous conductive material in the trench. The radio frequency circuit further may include a first dielectric substrate, a second dielectric substrate, with the trench being formed in the first and second dielectric substrates. A method of fabricating an electromagnetic circuit includes providing at least one dielectric substrate, machining a trench in the at least one dielectric substrate, and filling the trench with an electrically conductive material to form an electrically continuous conductor.

Abstract: A multilayer printed circuit board includes a first dielectric layer and a second dielectric layer, each layer having a top surface and a bottom surface. The first dielectric layer is positioned above the second dielectric layer with the bottom surface of the first dielectric layer facing the top surface of the second dielectric layer. The top surface of the second dielectric layer has a conductive trace. The second dielectric layer has a through-hole that extends through the conductive trace. The multilayer printed circuit board includes an inverted pad interface structure including an inverted pad provided on the bottom surface of the first dielectric layer, a first solder layer provided on a surface of the inverted pad, a second solder layer provided on the conductive trace, and a copper wire positioned within the through-hole to provide the vertical and electrical connection with the conductive trace.

Abstract: A radio frequency connector includes a substrate, a first ground plane disposed upon the substrate, a signal conductor having a first contact point, with the first contact point being configured to electrically mate with a second contact point, and a first ground boundary configured to electrically mate with a second ground boundary, with the first ground boundary being formed as an electrically continuous conductor within the substrate.

Abstract: A method of manufacturing a power divider circuit includes milling a conductive material disposed upon a first substrate to form a signal trace. The signal trace includes a division from a single trace to two arm traces, with each of the two arm traces having a proximal end electrically connected to the single trace and a distal end electrically connected to each of two secondary traces. The method further includes depositing a resistive ink between the two distal ends to form a resistive electrical connection between the two arm traces, bonding a second substrate to the first substrate to substantially encapsulate the traces between the first substrate and the second substrate, and milling through at least one of the first substrate or the second substrate to provide access to at least one of the traces. A signal divider is further disclosed.

Abstract: A radio frequency circuit includes at least one dielectric substrate, a trench formed in the dielectric substrate, and an electrically continuous conductive material in the trench. The radio frequency circuit further may include a first dielectric substrate, a second dielectric substrate, with the trench being formed in the first and second dielectric substrates. A method of fabricating an electromagnetic circuit includes providing at least one dielectric substrate, machining a trench in the at least one dielectric substrate, and filling the trench with an electrically conductive material to form an electrically continuous conductor.

Abstract: Electromagnetic circuit structures and methods are provided for a circuit board that includes a hole disposed through a substrate to provide access to an electrical component, such as a signal trace line (or stripline), that is at least partially encapsulated (e.g., sandwiched) between substrates. The electrical component includes a portion substantially aligned with the hole, and an electrical conductor is disposed within the hole. The electrical conductor is soldered to the portion of the electrical component.

Abstract: A low profile array (LPA) includes an antenna element array layer having at least one Faraday wall, and a beamformer circuit layer coupled to the antenna element array layer. The beamformer circuit layer has at least one Faraday wall. The Faraday walls extends between ground planes associated with at least one of the antenna element array layer and the beamformer circuit layer.