The present disclosure provides a dual-band external antenna for an unmanned aerial vehicle (UAV) and a UAV. The dual-band external antenna for the UAV includes a substrate, a low-frequency oscillator region, a high-frequency oscillator region, a feed coaxial line and ground terminals. Two ground terminals are respectively electrically connected to a feed terminal of the feed coaxial line. An avoidance region for arranging the feed coaxial line is disposed in the low-frequency oscillator region or the high-frequency oscillator region. The low-frequency oscillator region includes a first low-frequency oscillator region and a second low-frequency oscillator region. The high-frequency oscillator region includes a first high-frequency oscillator region and a second high-frequency oscillator region that are vertically asymmetrically disposed on the front and back sides of the substrate.

This application provides a phase shifter and an electrically tunable antenna including the phase shifter, where the phase shifter includes a tuning accessory, and the tuning accessory includes a tuning portion for tuning input impedance of the phase shifter. One additional capacitance or inductance parameter is added in the phase shifter by using the tuning portion, to affect input impedance of a port, to further affect a port standing wave, thereby tuning the port standing wave by using the tuning accessory. In addition, the tuning accessory in this application is a molded part with a fixed structure.

This application provides a phase shifter and an electrically tunable antenna including the phase shifter, where the phase shifter includes a tuning accessory, and the tuning accessory includes a tuning portion for tuning input impedance of the phase shifter. One additional capacitance or inductance parameter is added in the phase shifter by using the tuning portion, to affect input impedance of a port, to further affect a port standing wave, thereby tuning the port standing wave by using the tuning accessory. In addition, the tuning accessory in this application is a molded part with a fixed structure.

A positive terminal of a battery may act as an antenna ground plane for communicating battery status information. The positive terminal of the battery may include a first electrically conductive external surface with a first surface area. The negative terminal of the battery may include a second electrically conductive external surface with a second surface area less than the first surface area. An antenna impedance matching circuit may be electrically connected between a communication circuit, an antenna, and the positive terminal of the battery. Thus the positive terminal of the battery may act as a ground plane for the antenna.

A positive terminal of a battery may act as an antenna ground plane for communicating battery status information. The positive terminal of the battery may include a first electrically conductive external surface with a first surface area. The negative terminal of the battery may include a second electrically conductive external surface with a second surface area less than the first surface area. An antenna impedance matching circuit may be electrically connected between a communication circuit, an antenna, and the positive terminal of the battery. Thus the positive terminal of the battery may act as a ground plane for the antenna.

A dual-feed loop antenna structure adapted to be disposed on a substrate includes two loop antennas and two open-loop grounding radiators. Each of the loop antennas is used for resonating at a first frequency band and a second frequency band and includes a feed-in end and a ground segment. The two open-loop grounding radiators are located between the two loop antennas. Each of the open-loop grounding radiators extends from the ground segment of the corresponding loop antenna. A coupling gap is formed between the two open-loop grounding radiators. One of the loop antennas and the open-loop grounding radiator connected thereto completely overlap the other loop antenna and the other open-loop grounding radiator connected thereto after being mirrored and reversed. An electronic device is further provided.

A dual-feed loop antenna structure adapted to be disposed on a substrate includes two loop antennas and two open-loop grounding radiators. Each of the loop antennas is used for resonating at a first frequency band and a second frequency band and includes a feed-in end and a ground segment. The two open-loop grounding radiators are located between the two loop antennas. Each of the open-loop grounding radiators extends from the ground segment of the corresponding loop antenna. A coupling gap is formed between the two open-loop grounding radiators. One of the loop antennas and the open-loop grounding radiator connected thereto completely overlap the other loop antenna and the other open-loop grounding radiator connected thereto after being mirrored and reversed. An electronic device is further provided.

The invention proposes a dipole radiator module, comprising a first and a second dipole radiator. The first dipole radiator comprises two first half-dipole components and two second half-dipole components, of which one is respectively perpendicular to one of the two first half-dipole components. On the respective at a right angle converging ends, at respective outer corner regions of the respective perpendicular to one another first and second half-dipole components, are disposed open areas with first legs, which are spaced apart and associated with each of the first and second half-dipole components, wherein the first legs exhibit a first length. Further comprised are two third half-dipole components, which form a first upper side of the first dipole emitter, and two fourth half-dipole components, of which one is respectively perpendicular to one of the two third half-dipole components, wherein on the respective at a right angle converging ends, at respective outer corner regions of the respective perpendicular to one another third and fourth half-dipole components, are disposed open areas with second legs, which are spaced apart and associated with each of the third and fourth half-dipole components, wherein the second legs exhibit a second length. The second dipole radiator [comprises] two fifth half-dipole components, which form a second underside of the second dipole radiator, as well as two sixth half-dipole components, of which one is respectively perpendicular to one of the two fifth half-dipole components, and wherein the respective at a right angle converging ends of respective outer corner regions of the respective perpendicular to one another fifth and sixth half-dipole components are conductively connected to one another. Further comprised are two seventh half-dipole components, as well as two eighth half-dipole components, of which one is respectively perpendicular to one of the two seventh half-dipole components, and wherein on the respective at a right angle converging ends, at respective outer corner regions of the respective perpendicular to one another seventh and eighth half-dipole components, are disposed open areas [with] third legs, which are spaced apart and associated with each of the seventh and eighth half-dipole components, wherein the third legs exhibit a third length.

The invention proposes a dipole radiator module, comprising a first and a second dipole radiator. The first dipole radiator comprises two first half-dipole components and two second half-dipole components, of which one is respectively perpendicular to one of the two first half-dipole components. On the respective at a right angle converging ends, at respective outer corner regions of the respective perpendicular to one another first and second half-dipole components, are disposed open areas with first legs, which are spaced apart and associated with each of the first and second half-dipole components, wherein the first legs exhibit a first length. Further comprised are two third half-dipole components, which form a first upper side of the first dipole emitter, and two fourth half-dipole components, of which one is respectively perpendicular to one of the two third half-dipole components, wherein on the respective at a right angle converging ends, at respective outer corner regions of the respective perpendicular to one another third and fourth half-dipole components, are disposed open areas with second legs, which are spaced apart and associated with each of the third and fourth half-dipole components, wherein the second legs exhibit a second length. The second dipole radiator [comprises] two fifth half-dipole components, which form a second underside of the second dipole radiator, as well as two sixth half-dipole components, of which one is respectively perpendicular to one of the two fifth half-dipole components, and wherein the respective at a right angle converging ends of respective outer corner regions of the respective perpendicular to one another fifth and sixth half-dipole components are conductively connected to one another. Further comprised are two seventh half-dipole components, as well as two eighth half-dipole components, of which one is respectively perpendicular to one of the two seventh half-dipole components, and wherein on the respective at a right angle converging ends, at respective outer corner regions of the respective perpendicular to one another seventh and eighth half-dipole components, are disposed open areas [with] third legs, which are spaced apart and associated with each of the seventh and eighth half-dipole components, wherein the third legs exhibit a third length.

An antenna device includes: a ground plane having an edge; a matching circuit; and a T-shaped antenna element including a first element and a second element extending from a feed point to a first and second end parts. The first element has a resonance frequency that is higher than a first frequency. The second element has a resonance frequency between a second frequency and a third frequency. A first value obtained by dividing a length from a corresponding point to a first bend part by the first wavelength is less than or equal to a second value obtained by dividing a length from the corresponding point to a second bend part by the second wavelength. An imaginary component of an impedance of the matching circuit takes a positive value at the first frequency and the second frequency and takes a negative value at the third frequency.