A stripline that is usable in a quantum application (q-stripline) includes a first polyimide film and a second polyimide film. The q-stripline further includes a first center conductor and a second center conductor formed between the first polyimide film and the second polyimide film. The q-stripline has a first pin configured through the second polyimide film to make electrical and thermal contact with the first center conductor.

A phased array antenna system is provided, including a feed structure and at least one phased array antenna element, wherein the at least one phased array antenna element includes a first impedance transformation unit, an MEMS phase-shifting multi-unit and an antenna. The first impedance transformation unit is connected to a feed structure, and the MEMS phase-shifting multi-unit is connected between the first impedance transformation unit and the antenna.

The present invention relates to the field of communications technologies and discloses a phase shifter and a feed network. The phase shifter includes at least one phase shift component. The phase shift component includes a substrate, a microstrip coupling structure disposed on a first plane of the substrate, a microstrip transmission line connected to and coplanar with the microstrip coupling structure, and a microstrip/coplanar-waveguide coupling structure, where the microstrip/coplanar-waveguide coupling structure includes a microstrip connected to and coplanar with the microstrip transmission line, and a coplanar waveguide disposed opposite to the microstrip on the substrate and coupled with the microstrip. A phase shifter using a microstrip/coplanar-waveguide coupling structure has a small volume and costs low, thereby facilitating feed network design.

[Technical problem] A conventional dielectric waveguide input/output structure has a strength of coupling which is adjusted by a length of an input/output electrode. However, there is a limitation in an adjustable range of the coupling, which makes it impossible to have an input/output structure with wider bandwidth. [Solution to the technical problem] A dielectric waveguide input/output structure is provided, which comprises an input/output point provided near the center on one side of a bottom surface of a rectangular parallelepiped-shaped dielectric body, wherein an outer periphery of the dielectric body is covered with an electrically conductive film, except for an L-shaped lateral part extending along an edge of the bottom surface from opposite sides of the input/output point and for a surrounding part of the input/output point in a lateral surface with which the input/output point is in contact.

A vehicle having a communication system is disclosed. The system includes two electrical couplings, coupled by way of a rotary joint having a bearing waveguide. Each electrical coupling includes an interface waveguide configured to couple to external signals. Each electrical coupling also includes a waveguide section configured to propagate electromagnetic signals between the interface waveguide and the bearing waveguide of the rotary joint. Additionally, the rotary joint is configured to allow one electrical coupling to rotate with respect to the other electrical coupling. An axis of rotation of the rotary joint is defined by a center of a portion of the waveguides. Yet further, the rotary joint allows electromagnetic energy to propagate between the waveguides of the electrical couplings.

A vehicle having a communication system is disclosed. The system includes two electrical couplings, coupled by way of a rotary joint having a bearing waveguide. Each electrical coupling includes an interface waveguide configured to couple to external signals. Each electrical coupling also includes a waveguide section configured to propagate electromagnetic signals between the interface waveguide and the bearing waveguide of the rotary joint. Additionally, the rotary joint is configured to allow one electrical coupling to rotate with respect to the other electrical coupling. An axis of rotation of the rotary joint is defined by a center of a portion of the waveguides. Yet further, the rotary joint allows electromagnetic energy to propagate between the waveguides of the electrical couplings.

A method of forming a semiconductor structure is provided. A first inter-level dielectric (ILD) layer is formed overlying a molding layer. The first ILD layer is patterned to form a plurality of first openings. A first lower transmitter electrode and a first lower receiver electrode are formed by depositing a first metal material within the plurality of first openings. A first dielectric waveguide is formed overlying the first ILD layer, the first lower transmitter electrode and the first lower receiver electrode. A second ILD layer is formed overlying the first dielectric waveguide and includes a plurality of second openings. A second lower transmitter electrode and a second lower receiver electrode are formed by depositing a second metal material within the plurality of second openings. A second dielectric waveguide is formed overlying the second ILD layer, the second lower transmitter electrode and the second lower receiver electrode.

A method to design and assemble a connector for the transition between a coaxial cable and a microstrip line involves in connecting a coaxial connector in series with a metallic ring to form a new coaxial connector, wherein the thickness of the metallic ring and the diameter of its through hole are important design parameters to determine the frequency response of the transition. By properly selecting their values and connecting the new coaxial connector to the microstrip line, a resonant response caused by the excitation of the first higher-order mode of the original coaxial connector can be attenuated or even eliminated from the frequency response. Thus, the method improves the insertion loss of the transition at high frequencies, and increases its 1-dB passband. Note that the signal line of the microstrip line is not inserted into the through hole of the metallic ring in the final assembly of the transition.

An antenna module includes a dielectric layer in a form of a flat plate, a ground electrode, a radiating element, and a wiring cable. The ground electrode is arranged on a lower surface of the dielectric layer. The radiating element is arranged on an upper surface of the dielectric layer as being opposed to the ground electrode. The wiring cable faces a side surface of the dielectric layer, and includes a ground electrode and a power feeder line that conveys a radio frequency signal to the radiating element. The wiring cable is smaller in thickness than the dielectric layer. The power feeder line and the ground electrode are electrically connected to the radiating element and the ground electrode, respectively. The ground electrode is arranged at a position different from a position of the ground electrode in a direction of thickness of the dielectric layer.

An antenna module includes a dielectric layer in a form of a flat plate, a ground electrode, a radiating element, and a wiring cable. The ground electrode is arranged on a lower surface of the dielectric layer. The radiating element is arranged on an upper surface of the dielectric layer as being opposed to the ground electrode. The wiring cable faces a side surface of the dielectric layer, and includes a ground electrode and a power feeder line that conveys a radio frequency signal to the radiating element. The wiring cable is smaller in thickness than the dielectric layer. The power feeder line and the ground electrode are electrically connected to the radiating element and the ground electrode, respectively. The ground electrode is arranged at a position different from a position of the ground electrode in a direction of thickness of the dielectric layer.