Embodiments of a circuit, system, and method are disclosed. A beam switch to a beam with a beam configuration from another beam with another beam configuration is detected. In response to the detected beam switch: a tuner setting is determined for an antenna tuner of an antenna element in an antenna array which transmits the first beam with the first beam configuration based on the first beam configuration, the tuner setting associated with the first beam configuration; and an indication of the tuner setting is provided to an impedance matching system of the antenna tuner to compensate for a mismatch between an impedance of the antenna element and impedance of one or more other radio frequency (RF) components of an RF front-end having the antenna element and antenna tuner.

Embodiments of an access point (AP), station (STA) and method of communication are generally described herein. The AP may be included in a plurality of APs affiliated with a multi-link AP logical entity. As part of a multi-link AP logical entity, the plurality of APs may share a common medium access control (MAC) data service interface to an upper layer. The AP may exchange signaling with an STA as part of a multi-link setup process between the multi-link TP logical entity and a multi-link non-AP logical entity. The STA may be included in a plurality of STAs affiliated with the multi-link non-AP logical entity. The multi-link setup process may establish a link between each AP of the plurality of APs and a corresponding STA of the plurality of STAs.

Circuits and methods related to radio-frequency (RF) architectures having carrier aggregation. In some implementations, a method for performing carrier aggregation (CA) can include providing a duplexer configured to provide duplexing functionality for a first frequency band and a second frequency band with a common antenna. The method can further include providing a first amplification path and a second amplification path coupled to respective ports of the duplexer, each of the first amplification path and the second amplification path configured to amplify a signal in its respective frequency band, each amplification path including a transmit/receive (TX/RX) switch configured to provide time-division duplexing (TDD) functionality for the amplified signal and a received signal. In some implementations, the first frequency band includes a B39 band, and the second frequency band includes a B41 band.

Circuits and methods related to radio-frequency (RF) architectures having carrier aggregation. In some implementations, a method for performing carrier aggregation (CA) can include providing a duplexer configured to provide duplexing functionality for a first frequency band and a second frequency band with a common antenna. The method can further include providing a first amplification path and a second amplification path coupled to respective ports of the duplexer, each of the first amplification path and the second amplification path configured to amplify a signal in its respective frequency band, each amplification path including a transmit/receive (TX/RX) switch configured to provide time-division duplexing (TDD) functionality for the amplified signal and a received signal. In some implementations, the first frequency band includes a B39 band, and the second frequency band includes a B41 band.

A radio frequency module includes a transmit filter of Band A and Band B, a transmit amplifier, and a switch circuit and can perform CA using a transmit signal of Band A and a receive signal of Band B, a transmit band of Band B including a receive band of Band C. The switch circuit includes a switch switching connection between a common terminal and a first selection terminal, a switch switching connection between the common terminal and a second selection terminal, and a switch switching connection between the second selection terminal and a third selection terminal. The common terminal is connected to the transmit amplifier. The first selection terminal is connected to the transmit filter of Band A. The second selection terminal is connected to the transmit filter of Band B. The third selection terminal is connected to a receive path of Band C.

A radio frequency module includes a transmit filter of Band A and Band B, a transmit amplifier, and a switch circuit and can perform CA using a transmit signal of Band A and a receive signal of Band B, a transmit band of Band B including a receive band of Band C. The switch circuit includes a switch switching connection between a common terminal and a first selection terminal, a switch switching connection between the common terminal and a second selection terminal, and a switch switching connection between the second selection terminal and a third selection terminal. The common terminal is connected to the transmit amplifier. The first selection terminal is connected to the transmit filter of Band A. The second selection terminal is connected to the transmit filter of Band B. The third selection terminal is connected to a receive path of Band C.

A radio-frequency circuit includes a switch and three filters. The switch is connected to an antenna connecting terminal. One filter has a pass band corresponding to a first sub-band and is configured to connect to the antenna connecting terminal via the switch. The first sub-band is included in a first band used for TDD communication. Another filter has a pass band corresponding to a second sub-band included in the first band and is configured to connect to the antenna connecting terminal via the switch. There is a gap between the first sub-band and the second sub-band. The remaining filter has a pass band corresponding to a third sub-band and is configured to connect to the antenna connecting terminal via the switch. The third sub-band includes the first sub-band, the second sub-band, and the gap.

A single pole double throw (SPDT) switch with embedded attenuators includes a transmitter attenuator circuit directly connected to a common input of the SPDT switch, and a receiver attenuator circuit directly connected to the common input of the SPDT switch. Switches in the transmitter attenuator circuit and in the receiver attenuator circuit are selectively or individually set to an open state or to a closed state to directly connect the transmitter attenuator circuit or the receiver attenuator circuit to the common input. The selective setting of the states of the switches also determines a given amount of attenuation for the transmitter attenuator circuit or the receiver attenuator circuit.

Front end architectures are described that tailor duplexer characteristics to enable the removal of many of the impedance matching components typically included in a receive signal path between an antenna and receive amplifiers and in a transmit signal path between transmit amplifiers and the antenna. By tailoring duplexer characteristics, targeted impedance matching can be achieved for front end architectures. This enables the front-end architecture to impedance match without including typical impedance matching components along a signal path between the antenna and an amplifier. This can be implemented on the transmit signal path (e.g., between a power amplifier (PA) and the antenna), on the receive signal path (e.g., between the antenna and a low noise amplifier (LNA)), or both the transmit signal path and the receive signal path. Thus, the disclosed front end architectures are configured to reduce or eliminate the number of components required for impedance matching.

A high frequency switch configured to switch paths of differential signals arranged in an integrated circuit. The high frequency switch includes a pair of pole terminals and a plurality of pairs of throw terminals. The pair of pole terminals constitutes one port. Each pair of throw terminals constitutes another port.