A radio-frequency module includes a power amplifier, a low noise amplifier, a first switch connected to an antenna connection terminal, a first filter, and a module substrate. The first filter has a passband including a first communication band for Time Division Duplex, has a first end connected to the antenna connection terminal via the first switch, has a second end connected to an output terminal of the power amplifier or an input terminal of the low noise amplifier. The module substrate has the power amplifier, the low noise amplifier, the first switch, and the first filter arranged thereon. The first filter is arranged between the power amplifier and the first switch and between the power amplifier and the low noise amplifier in a plan view of the module substrate.

Systems, methods, and apparatuses, including electronic devices and computer-readable storage media, for adaptively switching wireless connections between antennas of a wearable electronic device and a host electronic device. One device includes a wearable electronic device with a first and second housing, each housing including two or more antennas. The wearable electronic device is configured to establish and monitor a wireless cross-link between two antennas in different housings, or between antennas in one housing and antennas of a host electronic device. The wearable electronic device can monitor the integrity of the wireless cross-link, and establish an updated cross-link in response to the wireless cross-link not meeting a predetermined integrity threshold. The wearable electronic device can monitor a wireless cross-head link between housings of a wearable electronic device at the same time as a wireless cross-body link between the wearable electronic device and the host electronic device.

Systems, methods, and apparatuses, including electronic devices and computer-readable storage media, for adaptively switching wireless connections between antennas of a wearable electronic device and a host electronic device. One device includes a wearable electronic device with a first and second housing, each housing including two or more antennas. The wearable electronic device is configured to establish and monitor a wireless cross-link between two antennas in different housings, or between antennas in one housing and antennas of a host electronic device. The wearable electronic device can monitor the integrity of the wireless cross-link, and establish an updated cross-link in response to the wireless cross-link not meeting a predetermined integrity threshold. The wearable electronic device can monitor a wireless cross-head link between housings of a wearable electronic device at the same time as a wireless cross-body link between the wearable electronic device and the host electronic device.

A radiofrequency frontend device includes a transceiver configured to transmit and receive electromagnetic radiation in a Millimeter wave (mmWave) radio frequency (RF) spectrum. One or more application programming interface (API) interface devices are configured to receive API calls from a remote source. A processor is coupled to the one or more API interface devices and the transceiver. The radiofrequency frontend device also includes a memory comprising programmed instructions stored in the memory. The processor is configured to execute the programmed instructions stored in the memory to receive one or more API calls from the one or more API interface devices for monitoring or controlling the transceiver and execute one or more monitor or control functions for the transceiver based on the received API calls from the remote source. A method of making a radiofrequency frontend device is also disclosed.

A radiofrequency frontend device includes a transceiver configured to transmit and receive electromagnetic radiation in a Millimeter wave (mmWave) radio frequency (RF) spectrum. One or more application programming interface (API) interface devices are configured to receive API calls from a remote source. A processor is coupled to the one or more API interface devices and the transceiver. The radiofrequency frontend device also includes a memory comprising programmed instructions stored in the memory. The processor is configured to execute the programmed instructions stored in the memory to receive one or more API calls from the one or more API interface devices for monitoring or controlling the transceiver and execute one or more monitor or control functions for the transceiver based on the received API calls from the remote source. A method of making a radiofrequency frontend device is also disclosed.

A method and circuit for controlling the compensation for channel mismatches are used in an electronic device which includes a signal transmission circuit or a signal receiving circuit that have two channels. The electronic device further includes a channel mismatch compensation circuit. The method includes: (A) determining a frequency of a test signal; (B) causing the test signal to pass through the signal transmission circuit or the signal receiving circuit, and measuring an image signal; (C) adjusting a compensation parameter of the channel mismatch compensation circuit to change an amplitude of the image signal; (D) determining, according to the amplitude of the image signal, a target compensation parameter of the channel mismatch compensation circuit, the target compensation parameter corresponding to the frequency of the test signal; (E) repeating steps (A) to (D) to obtain multiple target compensation parameters; and (F) determining a compensation mechanism based on the target compensation parameters.

A method and circuit for controlling the compensation for channel mismatches are used in an electronic device which includes a signal transmission circuit or a signal receiving circuit that have two channels. The electronic device further includes a channel mismatch compensation circuit. The method includes: (A) determining a frequency of a test signal; (B) causing the test signal to pass through the signal transmission circuit or the signal receiving circuit, and measuring an image signal; (C) adjusting a compensation parameter of the channel mismatch compensation circuit to change an amplitude of the image signal; (D) determining, according to the amplitude of the image signal, a target compensation parameter of the channel mismatch compensation circuit, the target compensation parameter corresponding to the frequency of the test signal; (E) repeating steps (A) to (D) to obtain multiple target compensation parameters; and (F) determining a compensation mechanism based on the target compensation parameters.

An RF filter comprising a resonator element and a polymer composition is provided. The polymer composition contains an aromatic polymer and has a melting temperature of about 240° C. or more. The polymer composition exhibits a dielectric constant of about 5 or less and dissipation factor of about 0.05 or less at a frequency of 10 GHz.

An RF filter comprising a resonator element and a polymer composition is provided. The polymer composition contains an aromatic polymer and has a melting temperature of about 240° C. or more. The polymer composition exhibits a dielectric constant of about 5 or less and dissipation factor of about 0.05 or less at a frequency of 10 GHz.

A controller area network including one or more first network nodes biased from a first power supply voltage, and a second network node biased from a second, lower, power supply voltage. The second network node includes a transmitter driving a differential voltage onto bus lines to communicate a dominant bus state at a second dominant state common mode voltage, a receiver coupled to the bus lines, sense circuitry to sense a common mode voltage at the bus lines, and control circuitry to control a recessive state common mode voltage in response to the sensed dominant state common mode voltage.