Aspect of the disclosure provide an antenna structure and electronic equipment. The antenna structure can include a nonmetallic frame, a radiator, and a Synthetic Aperture Radar (SAR) sensor. The radiator can be suspended inside the nonmetallic frame. The SAR sensor is connected to the radiator. Further, the SAR sensor can be configured for detecting capacitance between the radiator and a user.

An electronic device, according to one embodiment of the present invention, comprises: an antenna; and a photo conductive device electrically connected to the antenna, wherein the photo conductive device may comprise: a first layer including a plurality of conductive elements disposed to be spaced apart at a specified interval; a second layer disposed above the first layer and including at least one light source capable of outputting light; and a third layer disposed between the first layer and the second layer and having a photo conductive member of which at least a portion is changed, by means of the light, to be conductive in order to electrically connect at least a portion of the plurality of conductive elements. Various other embodiments may be included.

The present disclosure provides an electronic device including a metal housing and a plurality of antennas operating at different frequency bands. A frame of the metal housing is provided with at least one gap, each frame segment of frame segments on both sides of each gap is configured as a radiation structure shared by at least one antenna. Each antenna includes a signal circuit and a matching circuit, the matching circuit is coupled in series between the signal circuit of the antenna where the matching circuit is located and the radiation structure, and configured to output a signal matching with an operating frequency band of the antenna where the matching circuit is located and filter out signals that are coupled from other antennas of the gap and match with operating frequency bands of other antennas of the gap.

An antenna resource scheduling method and device for improving radiation efficiency of an antenna in a sideband area of an operating band by obtaining an operating frequency of an antenna, where the operating frequency is a frequency currently used by the device during communication; determining an operating band based on the operating frequency, where the operating band is a band to which the operating frequency belongs; determining a target impedance parameter based on the operating band and the operating frequency; and adjusting an impedance parameter of an impedance circuit to the target impedance parameter.

An antenna resource scheduling method and device for improving radiation efficiency of an antenna in a sideband area of an operating band by obtaining an operating frequency of an antenna, where the operating frequency is a frequency currently used by the device during communication; determining an operating band based on the operating frequency, where the operating band is a band to which the operating frequency belongs; determining a target impedance parameter based on the operating band and the operating frequency; and adjusting an impedance parameter of an impedance circuit to the target impedance parameter.

An apparatus and associated method are provided involving a housing having a periphery configured to operate as a second antenna, a third antenna, and a fourth antenna. The periphery includes a top wall having a first slot formed therein, a first side wall having a second slot formed therein, and a second side wall having a third slot formed therein. The top wall is arranged between the first side wall and the second side wall, and a top portion of the periphery is defined between the second slot and the third slot. The top portion is divided into a first top side portion and a second top side portion via the first slot. Further, the first top side portion operates as the second antenna, and the second top side portion operates as both the third antenna and the fourth antenna.

An antenna structure includes a housing, a first feed source, and a second feed source. The first feed source is electrically coupled to a first radiating portion of the housing and adapted to provide an electric current to the first radiating portion. The second feed source is electrically coupled to one of a second radiating portion or a third radiating portion of the housing. The other one of the second radiating portion or the third radiating portion is electrically coupled to the first radiating portion.

An antenna structure includes a housing, a first feed source, and a second feed source. The first feed source is electrically coupled to a first radiating portion of the housing and adapted to provide an electric current to the first radiating portion. The second feed source is electrically coupled to one of a second radiating portion or a third radiating portion of the housing. The other one of the second radiating portion or the third radiating portion is electrically coupled to the first radiating portion.

The disclosure provides an antenna module adapted for an electronic device having a metal casing. The antenna module includes an antenna structure and a slot structure. The antenna structure includes a radiation portion, a feeding portion, a ground portion and an extension portion, wherein the feeding portion, the ground portion and the extension portion are connected to the radiation portion. The slot structure has an open end and a closed end, wherein the open end of the slot structure is adjacent to the extension portion of the antenna structure. The antenna structure is excited and resonates to generate a first antenna resonant mode, and the slot structure is coupled to the antenna structure and resonates to generate a second antenna resonant mode.

A diplexer is proposed. The diplexer is configured to transmit a first signal having a first frequency and a second signal having a second frequency. The diplexer includes a first transmitting port, a second transmitting port, a third transmitting port, a first frequency band unit and a second frequency band unit. The first transmitting port is configured to transmit the first signal. The second transmitting port is configured to transmit the second signal. The third transmitting port is configured to transmit the first signal and the second signal. The first frequency band unit includes a first filter and a resonant circuit. The first filter is configured to filter the second signal. The resonant circuit is electrically connected to the first filter. The second frequency band unit includes at least one second filter. The at least one second filter is configured to filter the first signal.