Abstract: The present disclosure relates to a satellite signal feeding module and circuit board structure. The circuit board includes a dielectric substrate, a plurality of grounding sheets, a plurality of top feed sheets, a plurality of bottom feed sheets, and a conductive layer. The dielectric substrate includes a main segment having an opening, a rib segment extending across a full width of the opening, and a plurality of extending segments connected to the main segment. The grounding sheets cover the rib segment and a majority portion of the main segment. The top feeding sheets and the bottom sheets cover the extending segments. The conductive layer is disposed in first holes disposed in the main segment and the rib segment for electrically coupling the grounding sheets. The conductive layer is further disposed in second holes in the extending segments for electrically coupling the top and bottom feeding sheets.

Abstract: An input/output apparatus of a multiplexer is provided, including: a main tap and at least two branch taps of the main tap, where each of the at least two branch taps is configured to couple to a different resonant cavity in the multiplexer, and the at least two branch taps include a first branch tap and a second branch tap; a coupling polarity of the first branch tap is opposite to that of the second branch tap; and a coupling calculation frequency of the second branch tap is closest to a coupling calculation frequency of the first branch tap. The input/output apparatus of the multiplexer enables two channels with closest frequencies to use different coupling polarities. Because the coupling polarities are different, signals naturally do not interfere with each other, and signal interference between channels is eliminated in principle. The embodiments of the present disclosure further provide a corresponding multiplexer.

Abstract: The present invention relates to the field of communications technology, and in particular, to technology related to impedance matching in communication technology, and in particular, to a dielectric phase shifting unit, dielectric phase shifter and base station antenna. It includes a feeding network and a dielectric plate for impedance matching and for moving along a predetermined path, an impedance matching portion of the dielectric plate being disposed on one end of the dielectric plate adjacent to an input port on the feeding network. The present invention not only reduces the number of impedance matching and network loss; it also reduces the equivalent electrical length of the entire network, effectively saving costs, reducing the complexity of disassembly and assembly of related components, and improves disassembly and assembly efficiency.

Abstract: A filter comprises a dielectric resonator element and a cylindrical waveguide cavity having a corrugated tube structure that surrounds the dielectric resonator element such that an outer encircling wall surface of the dielectric resonator element is in contact with an inner sidewall of the corrugated tube structure. The corrugated tube structure includes one or more spaced-apart corrugations configured to provide a spring-like action to controllably expand and contract the corrugated tube structure so that the dielectric resonator element can be controllably inserted and clamped within the cylindrical waveguide cavity. The geometry of the spaced-apart corrugations can be selected to define a rotationally asymmetric corrugated tube structure configured to split a plurality of fundamental modes of electromagnetic waves within the filter.

Abstract: Wideband power combiners and splitters are provided herein. In certain embodiments, a power combiner/splitter is implemented with a first coil connecting a first port and a second port, and a second coil connecting a third port and a fourth port. The first coil and the second coil are inductively coupled to one another. For example, the first coil and the second coil can be formed using adjacent conductive layers of a semiconductor chip, an integrated passive device, or a laminate. The power combiner/splitter further includes a fifth port tapping a center of the first coil and a sixth port tapping a center of the second coil. The fifth port and the sixth port serve to connect capacitors and/or other impedance to the center of the coils to thereby provide wideband operation.

Abstract: A power divider/combiner includes a first transmission line (TL) and two second TLs. The first TL has a first terminal that is for receiving or outputting a signal with a target wavelength, and a second terminal that is open circuited. Each of the second TLs is disposed adjacent to and spaced apart from the first TL so as to establish electromagnetic coupling therebetween. Each of the second TLs has a first terminal, and a second terminal that is distal from the first terminal of the first TL. The second terminals of the second TLs are for cooperatively outputting or receiving a pair of signals that have the target wavelength and that are in-phase. Each of the first and second TLs has a length that is a quarter of the target wavelength.

Abstract: The present disclosure relates to a multilayer electromagnetic waveguide that includes a plurality of layers forming guide channels for an electromagnetic wave, and at least one transition device including at least one dielectric layer between two guide channels, referred to as coupled guide channels, extending as an extension. Each transition device includes at least one adaptation channel extending in a longitudinal direction, and each adaptation channel is defined by two electrically conductive walls. At least one wall extends along the dielectric spacer layer from one end of the coupled guide channel, over a length suitable for optimizing the transmission of an electromagnetic wave between the two coupled guide channels.

Abstract: A splitter for use in an in-home network includes an input and a plurality of outputs including at least a first output and a second output. A split point is between the input and the plurality of outputs. A first resistor and a first capacitor are connected in series between the input and the split point. A second resistor and a second capacitor are connected in series between the split point and the first output. A third resistor and a third capacitor are connected in series between the split point and the second output. The input, the first output, and the second output form a resistive Wye-type splitter. A first path exists between the input and the first output. A second path exists between the input and the second output. The first path and the second path have a substantially equal series resistance, series impedance, insertion loss, and isolation.

Abstract: An ultra-wideband Ortho-Mode (OMT) Transducer with ridges is provided. The ultra-wideband OMT with ridges includes a mode separation cavity, a combining cavity and a matching cavity. The mode separation cavity is configured to separate waves transmitted by a common port into at least one TE01 mode and at least one TE10 mode. The combining cavity is connected to two side ports of the mode separation cavity, is configured to combine TE01 modes transmitted by the two side ports into one and output from a standard rectangular port. The matching cavity is connected to a through port of the mode separation cavity and is configured to smoothly transit at least one TE10 mode transmitted by the through port to the standard rectangular port for output. The ultra-wideband OMT with ridges further includes a first ridge, a second ridge, a third ridge, and a fourth ridge.

Abstract: A controllable phase control element comprises a drive unit and a holder, to which at least two polarizers are attached, which are arranged one behind the other in the direction of incidence of a wave. Each polarizer is designed in such a way that the polarizer can convert a circularly polarized signal into a linearly polarized signal. The drive unit is designed in such a way that the holder and thus the polarizers can be mounted over a freely selectable angular range.

Abstract: A phase-controlled antenna element includes a waveguide emitter with signal output or signal injection, into which a rotatable phase control element is introduced, and a drive unit. The phase control element comprises in this case a holder, at least two polarizers which are fastened to the holder, and a connecting element. Each of the at least two polarizers can convert a circularly polarized signal into a linearly polarized signal. The phase control element is rotatably fitted in the waveguide emitter and is connected to the drive unit with the aid of the connecting element in such a manner that the drive unit can rotate the phase control element about the axis of the waveguide emitter.

Abstract: A switch component includes a common terminal, at least two selection terminals, a switching circuit that selectively connects the common terminal to each of the at least two selection terminals, and an inductor. One end of the inductor is connected to one of the at least two selection terminals. The switching circuit is integrated with the inductor.

Abstract: A 3D electromagnetic bandgap circuit includes: a dielectric layer having a first surface and an opposing second surface; a spiral element positioned on the first surface; a first surrounding element positioned on the first surface and surrounding the spiral element, but does not touch with the spiral element; a plane element positioned on the second surface and including a notch; a second surrounding element positioned on the second surface and surrounding the plane element, but does not touch with the plane element, wherein the second surrounding element further includes a protruding portion extending toward the notch; a first via passing through the dielectric layer, the spiral element, and the protruding portion; a second via passing through the dielectric layer, the plane element, and the first surrounding element; and a third via passing through the dielectric layer, the plane element, and the first surrounding element.

Abstract: An ultra-wideband linear-to-circular polarizer is disclosed. In accordance with embodiments of the invention, the polarizer includes a plurality of cascaded waveplates having biaxial permittivity or cascaded anisotropic sheet impedances. Each waveplate/sheet has a principal axis rotated at different angles relative to an adjacent waveplate/sheet about a z-axis of a 3-dimensional x, y, z coordinate system. Each waveplate is composed of a unit cell of an artificial anisotropic dielectric. Each sheet impedance is composed of an anisotropic metallic pattern. The polarizer further includes impedance matching layers disposed adjacent the cascaded waveplates/sheets.

Abstract: A phase shifter for altering the phase of a radio frequency signal is disclosed herein. A Lange coupler is used having reflective ports that are coupled to artificial transmission lines. The artificial transmission lines provide a reflection transmission path, the length of which can be determined by digital control lines. Transistors placed along the length of the central trace provide independent paths to ground that serve to shorten the electrical length of the ATL. Accordingly, by selectively turning the transistors on/off, the electrical length of the ATL can be selected and thus the amount of phase delay introduced by the phase shifter.

Abstract: Waveguide transition devices for power-combining devices are disclosed. A waveguide transition device includes a coaxial waveguide section that is configured to concurrently receive electromagnetic output signals from a plurality of amplifiers and transition the electromagnetic output signals to a waveguide coupling section to form a combined and amplified electromagnetic signal. In turn, the waveguide coupling section transitions the combined and amplified electromagnetic signal to a waveguide output port. As disclosed herein, representative waveguide transition devices are configured to allow higher operating powers without typical device failure mechanisms. Spatial power-combining devices that include representative waveguide transition devices have improved power handling capabilities.

Abstract: Systems and methods for communicating electromagnetic signals and/or power and, more particularly for example, to power combiners and similar systems and methods for communicating electromagnetic signals and/or power generated by amplifiers to loads, are described herein. In at least example embodiment, a power amplifier system includes first and second amplifier circuits and a power combiner circuit coupled to each of the first and second amplifier circuits and having a first microstrip transmission line component, a slotline formation, and an additional coupling component that is capable of being at least indirectly coupled to a load, where the first microstrip transmission line component and additional coupling component are electromagnetically coupled by way of the slotline formation.

Abstract: A high speed circuit and a method for fabricating the same is disclosed. The high speed circuit has a printed circuit board. A pair of first and second differential traces are formed on a first surface of the printed circuit board. The differential traces carry an electrical signal. A partial loop extends through the printed circuit board. The partial loop includes first and second end slots under the first and second differential traces. The partial loop includes a pair of side slots substantially parallel to the differential traces. An anchor member connects the printed circuit board to an island formed by the first and second end slots and side slots. The anchor member forms a gap in one of the end slots or side slots. The length of the side slots and the length of the gap is selected to reduce a target common mode frequency from the electrical signal.

Abstract: Spatial power-combining devices and, in particular, spatial power-combining devices with filtering elements are disclosed. A spatial power-combining device includes a plurality of amplifier assemblies and each amplifier assembly includes an input antenna structure, an amplifier, an output antenna structure, and a filtering element. A filtering element may be an integral single component with an input signal conductor of the input antenna structure or an integral single component with an output signal conductor of the output antenna structure. In some aspects, a filtering element may be an integral single component with both the input signal conductor and the output signal conductor.

Abstract: There is provided a branch circuit that comprises a first conductor and a second conductor as at least two branches from a predetermined branch point, a first stub connected to the first conductor at a first point, and a second stub connected to the second conductor at a second point, wherein the first point is a point where a length of a portion between the predetermined branch point and the first point of the first conductor is set to a first length determined in accordance with a characteristic of the first stub, and the second point is a point where a length of a portion between the predetermined branch point and the second point of the second conductor is set to a second length determined in accordance with a characteristic of the second stub and is different from the first length.