An apparatus includes a switching circuit and a plurality of registers. The switching circuit may be configured to generate a plurality of control signals in response to an enable signal. One control signal at a time may be active while the enable signal is in a transfer state. The registers may be configured to (i) buffer a plurality of setting values received from a memory and (ii) present the setting values from a subset of the registers to a plurality of transceiver circuits while a corresponding control signal is active. The setting values may include a plurality of phase values and a plurality of gain values used in the transceiver circuits to steer a radio frequency beam. Each transceiver channel may update the setting values from the registers within a predetermined time after a corresponding control signal becomes active.

An RF transmitter with a power combiner and a differential amplifier is provided. The power combiner converts a differential output signal to a single-end output signal and transmits the single-end output signal to the antenna. The differential amplifier includes common-source input transistors, common-gate output transistors and a switch module. The common-source input transistors amplify a differential input signal and output an amplified differential signal. The common-gate output transistors, including sources electrically coupled to the common-source input transistors and drains electrically coupled to the power combiner, generate the differential output signal according to the amplified differential signal. The switch module is electrically coupled between the gates. The switch module electrically couples the gates of the common-gate output transistors if the RF transmitter is in operation and electrically isolates the gates if the RF receiver is in operation.

A wireless communication device includes a first low-noise amplifier (LNA). The wireless communication device also includes a first LNA load circuit coupled to an output of the LNA. The wireless communication device further includes a power splitter switchably coupled to the first LNA load circuit. The power splitter includes a negatively coupled transformer and is switchably coupled to multiple outputs.

Systems and methods combine a test signal with a wanted (downlink or uplink) signal at an input of a duplexer of a communication device, and receive the test signal at an output of the duplexer. The test signal may include a radio frequency signal having less power than the wanted signal to avoid interference, or a digital signal that is added to or extracted from the wanted signal when the wanted signal does not have a radio frequency. A processor of the communication device causes the duplexer to operate in a tuning state (e.g., to transmit signals having a transmission frequency and receive signals having a receive frequency). The measurement system determines a difference or ratio in power between the test signal at the duplexer output and the duplexer input, and adjusts the tuning state based on the difference or ratio (e.g., to decrease or minimize the difference or ratio).

A system having a set of power amplifiers each having a primary inductive structure configured to provide an output signal. A secondary inductive structure is configured to inductively couple to each of the primary inductive structures. A transmission line is provided with a signal trace and a ground trace. The signal trace of the transmission line is connected to a first end of the secondary inductive structure. A return path from a second end of the secondary inductive structure is coupled via a resonant network to the ground trace of the transmission line, in which the return path is spaced away from the secondary inductive structure to minimize inductive coupling to the primary structures.

Systems and methods combine a test signal with a wanted (downlink or uplink) signal at an input of a duplexer of a communication device, and receive the test signal at an output of the duplexer. The test signal may include a radio frequency signal having less power than the wanted signal to avoid interference, or a digital signal that is added to or extracted from the wanted signal when the wanted signal does not have a radio frequency. A processor of the communication device causes the duplexer to operate in a tuning state (e.g., to transmit signals having a transmission frequency and receive signals having a receive frequency). The measurement system determines a difference or ratio in power between the test signal at the duplexer output and the duplexer input, and adjusts the tuning state based on the difference or ratio (e.g., to decrease or minimize the difference or ratio).

Disclosed is a cable module comprising a cable and a notch filter including a metal foil and a plurality of capacitors, wherein the metal foil is wrapped around the cable, wherein the metal foil includes a first through section and a second through section respectively arranged on opposite sides of the cable For an antenna to be placed in the through sections to capture frequency signals of the core wire by connecting to the detection device, and then the frequency signals can be collected and transmitted to the detection device for comparison and analysis, allowing for the detection of defective product. Thus, the said design eliminates the need for cumbersome disassembly of the notch filter product before detection thereof, thereby streamlining the detection process and making cable testing more efficient and precise.

A circuit includes a common terminal, a first terminal, and a second terminal. The common terminal is coupled to first and second circuit branches at a branch node. The first and second circuit branches include a first and second quarter wavelength transmission line having a first end coupled to the branch node and a second end coupled to the first and second terminals. The first and second terminals are coupled together via a branch-interconnection arrangement. The circuit includes a first switched arrangement with a first switch having a first and second switch-terminal. The first switch-terminal is coupled to the common terminal, and a first resistor and a first capacitor are arranged in parallel and coupled between the second switch-terminal and a reference terminal. The circuit also includes a second switched arrangement coupled to the first terminal. The first quarter wavelength transmission line is coupled between the first and second switched arrangements.