A self-controlled radio frequency (RF) filtering unit that may include (i) a frequency bank that comprises first till fourth band pass filters (BPFs) having first till fourth frequency bands respectively; wherein at least one harmonic of at least one fundamental frequency within the first frequency band pass an interference risk for at least one other frequency band; (ii) a measurement circuit configured to measure the input power received in two or more frequency bands and to provide a power measurement result; (ii) an input RF switch comprising a first RF switch input port, a first RF switch output port, and a second RF switch output port; wherein input RF switch is configured to select a selected RF switch output port, based at least in part on the power measurement result, out of the first and second RF switch output ports; wherein the first RF switch output port is RF coupled to an input of the second BPF; wherein the second RF switch output port is RF coupled to inputs of the first BPF, the third BPF and the fourth BPF; and (ii) an output RF switch comprising a second RF switch input port, a third RF switch input port, and a third RF switch output port; wherein output RF switch is configured to select, based at least in part on the power measurement result, a selected RF switch input port out of the second and third RF switch input ports; wherein the second RF switch input port is RF coupled to outputs of the first BPF and the second BPF; and wherein the third RF switch input port is RF coupled to outputs of the third BPF and the fourth BPF.

Provided is an electronic device that includes first and second housings, a display, a connecting member connecting the first and second housings, first and second conductive members, and a wireless communication circuit. The first housing includes a first side facing a first direction, a second side facing a second direction opposite to the first direction, and a first lateral side surrounding at least part of a space between the first side and the second side. The second housing includes a third side facing a third direction, a fourth side facing a fourth direction opposite to the third direction, and a second lateral side surrounding at least part of a space between the third side and the fourth side. The connecting member connects the first and second housings such that folding of the first and second housings results in the first and second lateral sides abutting against each other.

Provided is an electronic device that includes first and second housings, a display, a connecting member connecting the first and second housings, first and second conductive members, and a wireless communication circuit. The first housing includes a first side facing a first direction, a second side facing a second direction opposite to the first direction, and a first lateral side surrounding at least part of a space between the first side and the second side. The second housing includes a third side facing a third direction, a fourth side facing a fourth direction opposite to the third direction, and a second lateral side surrounding at least part of a space between the third side and the fourth side. The connecting member connects the first and second housings such that folding of the first and second housings results in the first and second lateral sides abutting against each other.

The present disclosure relates to an RF connector for base station antennas, which comprises an inner conductor, an outer conductor, and an insulator between the inner conductor and the outer conductor; wherein the inner conductor and the outer conductor of the RF connector are formed of conductive polymer, and the RF connector is manufactured through a co-extrusion molding process. In addition, the present disclosure also relates to an antenna assembly and a base station antenna.

The present disclosure relates to an RF connector for base station antennas, which comprises an inner conductor, an outer conductor, and an insulator between the inner conductor and the outer conductor; wherein the inner conductor and the outer conductor of the RF connector are formed of conductive polymer, and the RF connector is manufactured through a co-extrusion molding process. In addition, the present disclosure also relates to an antenna assembly and a base station antenna.

A wireless device comprises a radiating system that comprises and a radiating structure that operates in at least two frequency regions. The radiating structure comprises: a ground plane layer having a first connection point; a single radiation booster having a first connection point; a radiofrequency system comprising a first input port, a plurality of external output ports, and a plurality of branches, at least some of the plurality of branches being connected to a common point connected to the first input port, wherein each of the plurality of external output ports provides operation in at least one of the at least two frequency regions of operation; and a first internal port defined between the first connection point of the radiation booster and the first connection point of the ground plane layer, the first internal port being connected to the first input port of the radiofrequency system.

A wireless device comprises a radiating system that comprises and a radiating structure that operates in at least two frequency regions. The radiating structure comprises: a ground plane layer having a first connection point; a single radiation booster having a first connection point; a radiofrequency system comprising a first input port, a plurality of external output ports, and a plurality of branches, at least some of the plurality of branches being connected to a common point connected to the first input port, wherein each of the plurality of external output ports provides operation in at least one of the at least two frequency regions of operation; and a first internal port defined between the first connection point of the radiation booster and the first connection point of the ground plane layer, the first internal port being connected to the first input port of the radiofrequency system.

This application provides a multi-band antenna. The antenna includes a feeder and a radiating element connected to the feeder, and further includes: a first notch structure, where the first notch structure is located on a side of the radiating element and is coupled to the radiating element; and a second notch structure, where the second notch structure is located on a side of the first notch structure and far from the radiating element, and an end that is of the second notch structure and that is far from the radiating element is grounded. The first notch structure may be selectively connected to the ground or to the second notch structure. The first notch structure may be connected to the second notch structure in some embodiments using a first tuning device.

This application provides a multi-band antenna. The antenna includes a feeder and a radiating element connected to the feeder, and further includes: a first notch structure, where the first notch structure is located on a side of the radiating element and is coupled to the radiating element; and a second notch structure, where the second notch structure is located on a side of the first notch structure and far from the radiating element, and an end that is of the second notch structure and that is far from the radiating element is grounded. The first notch structure may be selectively connected to the ground or to the second notch structure. The first notch structure may be connected to the second notch structure in some embodiments using a first tuning device.

An electronic device and an antenna structure thereof are provided. The antenna structure includes a first radiating member, a feeding member disposed on the first radiating member, a second radiating member, and a grounding member. A first predetermined gap is between the feeding member and the first radiating member. The feeding member, the first predetermined gap, and the first radiating member resonate to generate a low frequency band and a high frequency band. The second radiating member including a main body and a grounding part is disposed on the first radiating member. A second predetermined gap is between the main body and the first radiating member. The grounding part, the main body, and the second predetermined gap resonate to increase a bandwidth of the low frequency band. The grounding member is disposed on the first radiating member and electrically connected to the grounding part.