A radio-frequency module includes a switch performing switching of the connection between a common terminal and a selection terminal, a reception filter having a reception band in a band A as a passband, a transmission filter that has a transmission band in a band B as a passband and has an output terminal connected to the selection terminal, a filter that has the transmission band in a band B as an attenuation band and has an input terminal connected to the selection terminal, a reception path which connects the selection terminal and an input terminal of the reception filter and on which the filter is disposed, a bypass path which connects the selection terminal and the input terminal of the reception filter and on which no filter is disposed, and a transmission path which connects the selection terminal and a transmission terminal and on which the transmission filter is disposed.

Embodiments of the present disclosure relate to a spectrum control system. The system comprises one or more high frequency (HF) antennas, one or more multi-band (MB) antennas, and one or more datalinks. A spectrum management processor is configured to receive signals from the one or more HF and MB antennas and the one or more datalinks, and switch to one or more alternate radio-frequency (RF) channels for communications and/or position, navigation, and timing (PNT) information in response to a failure in a current communication channel and/or a global positioning system (GPS) signal.

The apparatus includes a first xPlexer, coupled to a first antenna, including first and second filters; a second xPlexer, coupled to a second antenna, including third and fourth filters; a first switched xPlexer including fifth and sixth filters coupled to the second filter of the first xPlexer; a second switched xPlexer including seventh and eighth filters coupled to the fourth filter of the second xPlexer; a first transceiver coupled to the first filter of the first xPlexer and selectively coupled to the fifth filter of the first switched xPlexer; a second transceiver coupled to the third filter of the second xPlexer and selectively coupled to the seventh filter of the second switched xPlexer; a third transceiver selectively coupled to either the fifth or sixth filter of the first switched xPlexer; and a fourth transceiver selectively coupled to the seventh or eighth filter of the second switched xPlexer.

A system for controlling an impedance matching circuitry can include an antenna, a receiving or transmitting circuitry, an impedance matching circuitry, a circuitry, and a controller. The impedance matching circuitry can be coupled between the antenna and the receiving or transmitting circuitry. The circuitry can be configured to set a value of an impedance of the impedance matching circuitry. The controller can be configured to determine, based on a state of an electronic device, that the electronic device is configured to perform one or more functions with one or more of a satellite radio navigation signal at a first or a second frequency, a wireless local area network signal at a third or a fourth frequency, or a personal area network signal at a fifth or a sixth frequency. The controller can be configured to control, in response to a determination of the state of the electronic device, the circuitry.

a high-power uplink and downlink switching device and a communication apparatus are disclosed. A radio frequency switch and a synchronization control module of the device cooperate. A circulator has a first port connected to an output end of a power amplification module, a second port connected to a second radio frequency port, and a third port connected to a low-noise amplifier module via a first radio frequency switch. The third port is further connected to a high-power load resistor and a second radio frequency switch via a first microstrip line, so as to be separately grounded. A radio frequency impedance from a first end to a second end of the first microstrip line is in a high-impedance state.

Radio frequency switches with improved switching speed are provided. In certain embodiments, an RF switching circuit includes a FET switch including a gate, a digital buffer configured to provide a first output voltage to the gate of the FET during a steady-state, and a fast switching circuit in parallel with the digital buffer and configured to provide a second output voltage to the gate of the FET during a switching state. The fast switching circuit includes at least one charge pump configured to boost at least one supply voltage to a multiple of the at least one supply voltage. The fast switching circuit is configured to generate the second output voltage based on the boosted at least one supply voltage.

A radio-frequency module including a mounting substrate that has mounting faces opposed to each other; a PA that is mounted on the mounting face, that is a radio-frequency component, and that has an emitter terminal; a through electrode that is connected to the emitter terminal of the PA and that passes through the mounting faces of the mounting substrate; and a ground terminal connected to the through electrode.

A high-frequency signal transmission-reception circuit includes a plurality of band pass filter groups each including a plurality of band pass filter pairs; a first switch including a plurality of band pass filter-side terminal groups each including a plurality of band pass filter-side terminals, and an antenna-side terminal group; a plurality of couplers configured to output respective signal strengths of high-frequency signals transmitted on a plurality of transmission paths; and a second switch including an input terminal group electrically connected to the plurality of couplers, and an output terminal configured to output a detection signal output from one of the plurality of couplers. The first switch electrically connects one band pass filter-side terminal in one band pass filter-side terminal group and one antenna-side terminal, and also electrically connects one band pass filter-side terminal in another band pass filter-side terminal group and another antenna-side terminal.

A radio frequency module includes: a power amplifier; an inductor connected to the power amplifier; an external connection terminal that is connected to the power amplifier via the inductor and is configured to receive a power supply voltage from an outside source; a low-noise amplifier; a matching circuit connected to input of the low-noise amplifier; and a module substrate including a first principal surface and a second principal surface on opposite sides of the module substrate. The inductor is disposed on one of the first principal surface and the second principal surface, and the matching circuit is disposed on the other of the first principal surface and the second principal surface.

A radio frequency switch has an antenna end, a first signal end for transmitting a first radio frequency signal, a second signal end for transmitting a second radio frequency signal, a third signal end for transmitting a third radio frequency signal, a first series path having a first switch, a second series path having a second switch, a third series path having a third switch, a first shunt path coupled between the first signal end and a node, a second shunt path coupled between the second signal end and the node, a common path coupled between the node and a first reference voltage end, and a third shunt path coupled between the third signal end and a second reference voltage end. The first series path and the second series path are connected to a common ground pad via the common path.