A coupling device includes a plurality of couplers, a first coupled output port and a second coupled output port, wherein the plurality of couplers comprise a first coupler and a second coupler that are adjacent one another, and each of the first coupler and the second coupler comprises a main line and a subline, and for each of the first coupler and the second coupler: the subline includes a first section, a second section, and a third section, wherein the second section of the subline of the first coupler has a common segment with the first section of the subline of the second coupler.

A surface mountable coupler may include a monolithic base substrate having a first surface, a second surface, a length in an X-direction, and a width in a Y-direction that is perpendicular to the X-direction. A plurality of ports may be formed over the first surface of the monolithic base substrate including a coupling port, an input port, and an output port. The coupler may include a first thin film inductor and a second thin film inductor that is inductively coupled with the first thin film inductor and electrically connected between the input and output ports. A thin film circuit may electrically connect the first thin film inductor with the coupling port. The thin film circuit may include at least one thin film component.

Disclosed is a directional coupler having a coupler, a forward resistive attenuator, a reflected resistive attenuator, a forward compensation capacitor, and a reflected compensation capacitor. A forward coupler side arm and reflected coupler side arm of the coupler are configured to obtain a sample of forward energy and a sample of reflected energy from the coupler transmission line section. The forward resistive attenuator and reflected resistive attenuator are configured to attenuate the sample of forward energy and the sample of reflected energy. The forward compensation capacitor and the reflected compensation capacitor are configured to receive the attenuated sample of forward energy and the attenuated sample of reflected energy and produce a frequency-compensated sample of forward energy and a frequency-compensated sample of reflected energy.

A signal coupler (100) comprising: a main-transmission-line (114) that extends in a longitudinal direction within a substrate (102) between an input port and an output port; and a coupled-transmission-line (116) that extends in the longitudinal direction within the substrate (102) between a coupled port and a termination port. The coupled-transmission-line (116) is in a second layer (110). The main-transmission-line (114) comprises a first-portion (120) in a first layer (108), a second-portion (122) in a second layer (110), and a third-portion (124) in a third layer (112). At least part of the first-portion (120) is spaced apart from the coupled-transmission-line (116) in a depth direction. At least part of the second-portion (122) is spaced apart from the coupled-transmission-line (116) in the depth direction. At least part of the third-portion (124) is spaced apart from the coupled-transmission-line (116) in the depth direction.

A Wilkinson power divider includes an input line, a first branching line and a second branching line branching from the input line, a first output line coupled to a first end of an output side of the first branching line, a second output line coupled to a second end of an output side of the second branching line, a first stub coupled to the first end, a second stub coupled to the second end, an isolation resistor coupled between the first stub and the second stub, and a circuit branching from a first point between two ends of the first stub, and a second point between two ends of the second stub, and coupling between the first point and the second point. At least a portion of the first stub, at least a portion of the second stub, and the first circuit form a resonant circuit.

A 90-degree 3 dB coupler with an input port, an isolated port, a first output port, and a second output port has an input connector strip connected to the input port, and an isolated port connector strip connected to the isolated port. A first output connector strip is connected to the first output port, and a second output connector strip is connected to the second output port. A first interconnect strip is connected to the input connector strip and a second interconnect strip is connected to the isolated port connector strip. A first one of conductive coupled strips extend from the input connector strip to the second output connector strip, while a second one of the conductive coupled strips extend from the first interconnect strip to the second interconnect strip. A third one of the conductive coupled strips extends from the first interconnect strip to the second output connector strip.

A Docsis-MoCA coupled line directional coupler includes an input port, an output port, a coupled port, and a termination port. A first track connects the input port to the output port and a second track, which may be substantially parallel to the first track, connects the termination port to the coupled port. The first track and the second track are configured to form a variable coupling length so as to control, for instance, an isolation level between the output port and the coupled port to be less than a predetermined isolation level in a MoCA frequency band.

A radio frequency signal coupler includes an input port, an output port, a main transmission line coupled between the input port and the output port, and a coupled transmission line electromagnetically coupled to the main transmission line. The coupled transmission line includes a first transmission line, a second transmission line, and a switch configured to couple the first and second transmission lines during a first mode of operation and to decouple the first and second transmission lines during a second mode of operation. The radio frequency couple can be used in a front end module of a communications device, such as a mobile phone.

A directional coupler (1) includes a substrate (10), a main line (20) formed directly or indirectly on the substrate (10), sub-lines (21, 22 and 23) at least part of each of which is formed directly or indirectly on the substrate (10) along the main line (20), a switch (30) switching connections among end portions of the plurality of sub-lines (21, 22 and 23), and detection output terminals (FWD and REV) connected to the sub-line (21), wherein, when looking at the substrate (10) in plan, the end portions of the sub-lines (21, 22 and 23) are disposed on the same side as the detection output terminals (FWD and REV) relative to the main line (20), and the sub-line (21) to which the detection output terminals (FWD and REV) are connected is overlapped with or surrounded by the sub-lines (22 and 23).

A directional coupler includes a main line, a secondary line, and a variable terminator. The variable terminator includes a variable inductor. The variable inductor includes a plurality of inductors coupled in series with each other between an end portion of the secondary line and the ground and switches configured to bypass at least one inductor of the plurality of inductors.