The present disclosure relates to an adaptive antenna radome heating system (200, 300, 400) for a point to point radio link, where the adaptive antenna radome heating system comprises a processing unit (150, 220, 420) and at least one point to point radio link transceiver (TRX) (111, 121; 210A, 210B, 210C). Each TRX comprises an antenna radome (110, 120) having an antenna radome heating device (140, 141) configured to be activated by a control signal (R1, R2, RN). The processing unit (150, 220, 420) is arranged to determine an onset of accumulated precipitation on the antenna radome of the at least one TRX (111, 121; 210A, 210B, 210C) and to activate the corresponding antenna radome heating device (140, 141) by the control signal (R1, R2, RN) in response to determining the onset of accumulated precipitation.

The present disclosure relates to an adaptive antenna radome heating system (200, 300, 400) for a point to point radio link, where the adaptive antenna radome heating system comprises a processing unit (150, 220, 420) and at least one point to point radio link transceiver (TRX) (111, 121; 210A, 210B, 210C). Each TRX comprises an antenna radome (110, 120) having an antenna radome heating device (140, 141) configured to be activated by a control signal (R1, R2, RN). The processing unit (150, 220, 420) is arranged to determine an onset of accumulated precipitation on the antenna radome of the at least one TRX (111, 121; 210A, 210B, 210C) and to activate the corresponding antenna radome heating device (140, 141) by the control signal (R1, R2, RN) in response to determining the onset of accumulated precipitation.

An antenna structure includes a main radiator element, a parasitic radiator element, a feeder and at least one first high-impedance member. The parasitic radiator element is disposed in parallel with the main radiator element. The feeder is configured to electrically or electromagnetically couple the main radiator element. The at least one first high-impedance member directly contacts the parasitic radiator element and is configured to be electrically grounded.

An antenna structure includes a main radiator element, a parasitic radiator element, a feeder and at least one first high-impedance member. The parasitic radiator element is disposed in parallel with the main radiator element. The feeder is configured to electrically or electromagnetically couple the main radiator element. The at least one first high-impedance member directly contacts the parasitic radiator element and is configured to be electrically grounded.

Radio frequency signal boosters for high frequency cellular communications are provided herein. In certain embodiments, a signal booster system for providing high frequency wireless signal reception of a 5G network inside a building is provided. The signal booster system includes one or more auxiliary signal boosters for extending coverage within rooms of the building. For example, an auxiliary signal booster can include a donor unit located in a first room and having a base station antenna and booster circuitry integrated therewith. The auxiliary signal booster further includes a server unit located in a second room and having a having a mobile station antenna integrated therewith. The donor unit and the server unit are connected by a short cable.

Some embodiments of the present disclosure are directed to an antenna system for an airplane. The antenna system including an antenna system enclosure and a desiccant enclosure within the antenna system enclosure and having desiccant material positioned between an outside air pipe and an inside air pipe, the inside air pipe extending from the desiccant enclosure to open to an interior air volume of at least one component of the antenna system within the antenna system enclosure, the outside air pipe extending from the desiccant enclosure to ambient air outside the antenna system enclosure, and the desiccant material is configured to absorb moisture in the ambient air flowing from the outside air pipe to the inside air pipe through the desiccant enclosure while air pressure is being equalized from outside to inside the antenna system enclosure.

Some embodiments of the present disclosure are directed to an antenna system for an airplane. The antenna system including an antenna system enclosure and a desiccant enclosure within the antenna system enclosure and having desiccant material positioned between an outside air pipe and an inside air pipe, the inside air pipe extending from the desiccant enclosure to open to an interior air volume of at least one component of the antenna system within the antenna system enclosure, the outside air pipe extending from the desiccant enclosure to ambient air outside the antenna system enclosure, and the desiccant material is configured to absorb moisture in the ambient air flowing from the outside air pipe to the inside air pipe through the desiccant enclosure while air pressure is being equalized from outside to inside the antenna system enclosure.

According to an implementation, a computing device includes electronic circuitry, and an antenna and heat venting chamber having an antenna radiating element disposed in at least a first plane, a ground plane element disposed in at least a second plane, a first side wall member defining a plurality of perforations, and a second side wall member having a portion that is disposed opposite to the first side wall member, where the portion of the second side wall member defines at least one opening. The computing device includes a cooling system configured to vent heat generated by the electronic circuitry through the antenna and heat venting chamber.

According to an implementation, a computing device includes electronic circuitry, and an antenna and heat venting chamber having an antenna radiating element disposed in at least a first plane, a ground plane element disposed in at least a second plane, a first side wall member defining a plurality of perforations, and a second side wall member having a portion that is disposed opposite to the first side wall member, where the portion of the second side wall member defines at least one opening. The computing device includes a cooling system configured to vent heat generated by the electronic circuitry through the antenna and heat venting chamber.

An information handling system executing an integrated antenna power and cooling management system may comprise an antenna situated nearby components of the information handling system, a chassis enclosing the information handling system, the antenna, and a wireless interface device with a wireless radio to generate a signal to transmit data via the antenna, where the components and the chassis are capable of absorbing a total thermal heat capacity, the chassis having an outer surface coming into contact with human skin during execution of the information handling system, a temperature sensor to determine an operating temperature of the information handling system reaching a control point value, and a processor executing code instructions to estimate antenna thermal output during data transmission relative to the total thermal heat capacity of the components, based on the operating temperature of the information handling system, and control an active cooling system for cooling the chassis.