A directional coupler includes a main line for transmitting a high frequency signal, a sub line electromagnetically coupled to the main line, a termination circuit for terminating one end portion of the sub line, and a variable filter that has an input terminal and an output terminal and the input terminal is connected to another end portion of the sub line. The variable filter is a filter unit circuit having one frequency band as a pass band or a stop band, and in the filter unit circuit, a variable passive element for shifting a frequency in the pass band or the stop band is disposed.

A directional coupler may include a first coupled section comprising a first and a second coupled transmission lines, the first coupled transmission line having a first end coupled to an input port. The directional coupler may also include a second coupled section comprising a first and a second coupled transmission lines. The directional coupler may also include a third coupled section comprising a first and a second coupled transmission lines. The first coupled transmission line of the third coupled section has a first end coupled to a second end of the second coupled transmission line of the second coupled section and a second end coupled to an output port. The directional coupler may further include a delay section. A total electrical length of the first coupled section, the second coupled section, the third coupled section, and the delay section is about 90 degrees.

A 90° hybrid inductive-capacitive coupling stage includes two first stage terminals capable of forming two stage inputs or two stage outputs and two second stage terminals capable of respectively forming two stage outputs or two stage inputs. The coupling stage is advantageously modular having a first stage axis of symmetry and a second stage axis of symmetry orthogonal to each other with neighboring inductive metal tracks being overlaid in at least one crossing region to form both an inductive circuit and a capacitive circuit. The metal tracks are coupled to the first stage terminals and to the second stage terminals such that the two first stage terminals are situated on one side of the first stage axis of symmetry and the two second stage terminals are situated on the other side of the first stage axis of symmetry.

A directional coupler includes a substrate, a main line 121, a main line 122, and a sub-line. The main line 121 and the main line 122 each include a conductor pattern formed in the substrate, and are connected in parallel to each other. The sub-line includes a conductor pattern formed in the substrate. The sub-line is disposed at a position at least partially overlapping with the main line 121 in a plan view of the substrate.

A wireless communication system includes a first differential signal line, a differential coupler, and an electronic circuit. The differential coupler has a second differential signal line to perform wireless communication of a differential signal with the first differential signal line via electromagnetic field coupling. The electronic circuit is connected to the differential coupler via a wired transmission path to process the differential signal. A surface of a board or a ground pattern of the electronic circuit is inclined or upright with respect to the second differential signal line so as to separate away from a direction in which the first differential signal line extends.

This invention refers to hybrid coupler with the sum port and difference port located on the same side. The hybrid coupler can be efficiently integrated into the high frequency circuit with its simple structure, using common material. To achieve this purpose, the hybrid coupler in this invention consists of the following parts: sum port, difference port, output port 1, output port 2, connection line 1, connection line 2 and microstrip line.

Disclosed herein is an antenna device that includes a circuit layer having a filter circuit, an antenna layer stacked on the circuit layer and having a radiation conductor, a feed layer positioned between the circuit layer and the antenna layer and having a first feed pattern connected to the filter circuit and electromagnetically coupled to the radiation conductor, a first ground pattern provided between the antenna layer and the feed layer, and a second ground pattern provided between the circuit layer and the feed layer. The first and second ground patterns have first and second slots, respectively, at least partially overlapping each other as viewed in a stacking direction. The first feed pattern at least partially overlaps the radiation conductor and the first and second slots.

A directional coupler (1) includes a surface mounted component (10) and a mounting substrate (20) on which the surface mounted component (10) is mounted. Among a main line and a sub line of the directional coupler (1), the main line is formed of a first line (31) and a second line (32), one end (311) of the first line (31) and one end (321) of the second line (32) being connected to each other, the sub line is formed of a third line (33). The first line (31) and the third line (33) are formed in the surface mounted component (10). The second line (32) is formed on or in the mounting substrate (20). Furthermore, another end (312) of the first line (31) and another end (322) of the second line (32) may be connected to each other.

A superconducting on-chip coiled coupled-line 90 hybrid coupler is made of a series array of repeated cells of coiled transmission lines that are inductively and capacitively coupled. The coupler splits an incoming microwave signal into two output signals of roughly equal power and separated in phase from each other by roughly 90. The coupler can be incorporated into such superconducting electronic circuits as clock-distribution networks for reciprocal quantum logic (RQL) systems, as well as Josephson-based phase shifters and vector modulators.

A directional coupler (10) includes a main line (20), a sub-line (40), and a variable capacitor (60). At least part of the sub-line (40) is disposed along the main line (20). The variable capacitor (60) is connected between the main line (20) and the sub-line (40). The directional coupler (10) achieves a stable degree of coupling between the main line (20) and the sub-line (40).