A base station antenna includes a column of radiating elements comprising first and second sets of radiating elements, each radiating element being configured to operate in a first frequency band that has first and second sub-bands. The second set of radiating elements is located above and/or below the first set of radiating elements. The antenna further includes a feeding assembly that is configured to feed first RF signals that are in the first sub-band and second RF signals that are in the second sub-band to the column of radiating elements, where the feeding assembly is configured to partially attenuate sub-components of the second RF signals that are fed to the second set of radiating elements more than sub-components of the first RF signals that are fed to the second set of radiating elements.

A base station antenna includes a column of radiating elements comprising first and second sets of radiating elements, each radiating element being configured to operate in a first frequency band that has first and second sub-bands. The second set of radiating elements is located above and/or below the first set of radiating elements. The antenna further includes a feeding assembly that is configured to feed first RF signals that are in the first sub-band and second RF signals that are in the second sub-band to the column of radiating elements, where the feeding assembly is configured to partially attenuate sub-components of the second RF signals that are fed to the second set of radiating elements more than sub-components of the first RF signals that are fed to the second set of radiating elements.

A nonreciprocal phased-array antenna includes an array of resonant antennas a.sub.1, . . . , a.sub.n. During transmission, an outbound signal having a frequency f.sub.0 and a phase shift φ.sub.di caused by propagation through a data network feeds into each resonant antenna a.sub.i. Each resonant antenna a.sub.i upconverts the outbound signal using a modulation signal having a frequency f.sub.m and a phase shift φ.sub.mi caused by propagation through a modulation network to produce an upconverted radiated signal having a frequency f.sub.0+f.sub.m and a phase proportionate to φ.sub.di+φ.sub.mi. During reception, an inbound signal of frequency f.sub.0+f.sub.m is received at each resonant antenna a.sub.i and is downconverted using the modulation signal to produce a downconverted signal having a frequency f.sub.0 and a phase proportionate to −φ.sub.mi. After passing through the data network to the inbound port, the downconverted signal has a phase proportionate to φ.sub.di−φ.sub.mi.

An antenna module according to the present disclosure includes a control substrate including a control circuit, an antenna substrate mounted on the control substrate and including shield through holes and a plurality of first antenna patch conductors disposed side by side when viewed in a plan view, and filters each electrically connected to the shield through holes and including a high-frequency filter and a low-frequency filter. The control substrate or the antenna substrate includes internal antennas at positions each facing one of the plurality of corresponding first antenna patch conductors. When viewed in a plan view, the shield through holes and the filters are located between adjacent ones of the plurality of first antenna patch conductors.

An antenna module according to the present disclosure includes a control substrate including a control circuit, an antenna substrate mounted on the control substrate and including shield through holes and a plurality of first antenna patch conductors disposed side by side when viewed in a plan view, and filters each electrically connected to the shield through holes and including a high-frequency filter and a low-frequency filter. The control substrate or the antenna substrate includes internal antennas at positions each facing one of the plurality of corresponding first antenna patch conductors. When viewed in a plan view, the shield through holes and the filters are located between adjacent ones of the plurality of first antenna patch conductors.

An instrument landing system (ILS) is described. The ILS comprises a plurality of antennas and a plurality of antenna radio units (ARUs). Each ARU of the plurality of ARUs operates to generate a modulated RF signal provided to a different one of the plurality of antennas for transmission. The ILS further comprises a central processing unit that operates to control the ARUs to adjust synchronization between the modulated RF signal provided by the ARUs to the plurality of antennas for transmission.

Embodiments of this application disclose an antenna. The antenna may be applied to the field of automatic driving and the field of vehicle-to-everything, and the antenna includes a first radiating element and a first feed line. A first end of the first feed line is connected to the first radiating element. The first radiating element and the first feed line are arranged on a same surface of a dielectric substrate. The first feed line includes a first feed line segment, and an acute angle between the first feed line segment and a current direction of the first radiating element is greater than or equal to 20 degrees, and is less than or equal to 70 degrees. A feeding manner of the antenna is parallel feeding.

Embodiments of this application disclose an antenna. The antenna may be applied to the field of automatic driving and the field of vehicle-to-everything, and the antenna includes a first radiating element and a first feed line. A first end of the first feed line is connected to the first radiating element. The first radiating element and the first feed line are arranged on a same surface of a dielectric substrate. The first feed line includes a first feed line segment, and an acute angle between the first feed line segment and a current direction of the first radiating element is greater than or equal to 20 degrees, and is less than or equal to 70 degrees. A feeding manner of the antenna is parallel feeding.

An antenna package according to an exemplary embodiment includes an antenna unit, a printed circuit board including an antenna connection wiring electrically connected to the antenna unit, an antenna driving integrated circuit (IC) chip mounted on the printed circuit board and connected to the antenna connection wiring, and a touch sensor driving IC chip and a display driving IC chip mounted on the printed circuit board together with the antenna driving IC chip. The driving IC chips are integrated in a single printed circuit board to improve spatial and process efficiency.

An active radio-frequency (RF) sensing technology for determining the relative and/or absolute state (e.g., position, velocity, and/or acceleration) of a target object (e.g., a person, a car, a truck a lamp post, a utility pole, a building) is described. The sensors described herein operate in the Terahertz band (300 GHz to 3 THz). An active RF sensing device comprises a substrate and first and second semiconductor dies mounted on the substrate. The first semiconductor die has an RF transmit antenna array integrated thereon, and the transmit antenna array comprises a first plurality of RF antennas configured to generate an RF signals having frequency content in the 300 GHz-3 THz band. The second semiconductor die has an RF receive antenna array integrated thereon, and the receive antenna array comprises a second plurality of RF antennas configured to receive RF signals having frequency content in the 300 GHz-3 THz band.