An antenna coupling unit (ACU) is provided. The ACU includes a transmitter port, a receiver port, and an antenna port; a circulator isolating the transmitter port from the receiver port; a first waveguide coupling the transmitter port with the circulator. The transmitter port receives an outgoing from first external circuitry. The first waveguide includes a first filter that filters the outgoing before routing the outgoing signal to the antenna port. The ACU further includes a second waveguide coupling the circulator with the receiver port. The second waveguide includes a second filter that filters an incoming received through the antenna port before routing the incoming signal to the receiver port. The receiver port provides the filtered incoming to second external circuitry. The ACU further includes a third waveguide coupling the antenna port with the circulator. At least one of the first filter and the second filter is a tunable filter.

An antenna coupling unit (ACU) is provided. The ACU includes a transmitter port, a receiver port, and an antenna port; a circulator isolating the transmitter port from the receiver port; a first waveguide coupling the transmitter port with the circulator. The transmitter port receives an outgoing from first external circuitry. The first waveguide includes a first filter that filters the outgoing before routing the outgoing signal to the antenna port. The ACU further includes a second waveguide coupling the circulator with the receiver port. The second waveguide includes a second filter that filters an incoming received through the antenna port before routing the incoming signal to the receiver port. The receiver port provides the filtered incoming to second external circuitry. The ACU further includes a third waveguide coupling the antenna port with the circulator. At least one of the first filter and the second filter is a tunable filter.

A circulator plate for a microwave radio system is disclosed. The circulator plate includes a circulator including a first port, a second port, and a third port; a first isolator including an input port and an output port; a second isolator including an input port and an output port; and a splitter including an input port, a first output port, and a second output port. The output port of the first isolator is coupled to the first port of the circulator. The input port of the second isolator is coupled to the third port of the circulator. The input port of the splitter is coupled to the output port of the second isolator. The first output port of the splitter is configured to be coupled to a first receiver. The second output port of the splitter is configured to be coupled to a second receiver.

A circulator plate for a microwave radio system is disclosed. The circulator plate includes a circulator including a first port, a second port, and a third port; a first isolator including an input port and an output port; a second isolator including an input port and an output port; and a splitter including an input port, a first output port, and a second output port. The output port of the first isolator is coupled to the first port of the circulator. The input port of the second isolator is coupled to the third port of the circulator. The input port of the splitter is coupled to the output port of the second isolator. The first output port of the splitter is configured to be coupled to a first receiver. The second output port of the splitter is configured to be coupled to a second receiver.

A high-frequency component for guiding electromagnetic high-frequency waves includes a hollow conductor structure with a housing and a field-guiding region. The housing includes at least in part plastics material and the housing wall surface facing the field-guiding region includes a metal coating. Two or more parallel-guided cooling ducts can be integrated into the housing, the mutual spacing of which varies in accordance with a field density of an energy-guiding mode.

A compact antenna feeder and associated circulator plate are disclosed. The antenna feeder includes: an orthomode transducer (OMT) polarizer, a first circulator and a second circulator. The OMT -polarizer includes a septum, a first port, a second port, and a third port. The first circulator is coupled to the first port of the OMT polarizer to define one orthogonally polarized microwave signal path between the first circulator and the third port of the OMT-polarizer. The second circulator is coupled to the second port of the OMT polarizer to define another orthogonally polarized microwave signal path between the second circulator to the third port of the OMT-polarizer. The OMT polarizer includes a waveguide with the septum located therein separating the two orthogonally polarized microwave signal paths. The septum has a base mounted on the circulator plate and a step-shape body extending from the base and out of the circulator plate.

A compact six-port Photonic Crystal (PhC) circulator includes a hexagonal PhC branch waveguide and six waveguide ports, wherein six PhC branch waveguides respectively correspond to the six waveguide ports, and the six waveguide ports respectively are symmetrically distributed at the periphery of PhCs. One second dielectric material column is arranged at the center of the hexagonal PhC waveguide. Six identical magneto-optical material columns respectively are arranged at first adjacent positions of the second dielectric material column. Six identical third dielectric material columns respectively are arranged at second adjacent positions of the second dielectric material column. An electromagnetic signal is inputted from any one of the waveguide ports and is outputted from the next waveguide port adjacent thereto, while the remaining waveguide ports are in a signal isolated state, thus forming unidirectional circular transmission.

A structure can include a first element and a carrier bonded to the first element along an interface. A waveguide can be defined at least in part along the interface between the first element and the carrier. The waveguide can comprise an effectively closed metallic channel and a dielectric material within the effectively closed metallic channel, as viewed from a side cross-section of the structure. Various millimeter-wave or sub-terahertz components or circuit structures can also be created based on the waveguide structures disclosed herein.

A method for making a composite substrate circulator comprising disposing a plurality of sleeves about a plurality of rods, disposing the plurality of rods and the plurality of sleeves in a plurality of openings in a block to form an assembly, and dividing the assembly to form a plurality of plates. The magnetic saturation (4PiMs) values of the rods and sleeves are chosen to decrease radially (rod has the highest 4PiMs). In addition, a method for making a composite substrate circulator component can include disposing a sleeve about a rod, and disposing the rod and the sleeve in an opening in a block to form an assembly. The rod and/or the sleeve can have a plurality of longitudinally spaced recesses. Additionally, the method can include dividing the assembly at the longitudinally spaced recesses to form a plurality of plates.

Apparatus, and corresponding method, relates generally to a microelectronic device. In such an apparatus, a first conductive layer is for providing a lower interior surface of a circuit structure. A plurality of wire bond wires are interconnected to the lower interior surface and spaced apart from one another for providing at least one side of the circuit structure. A second conductive layer is for providing an upper interior surface of the circuit structure spaced apart from the lower interior surface by and interconnected to the plurality of wire bond wires. The plurality of wire bond wires, the first conductive layer and the second conductive layer in combination define at least one opening in the at least one side for a signal port of the circuit structure. Such circuit structure may be a signal guide circuit structure, such as for a signal waveguide or signal cavity for example.