An radiating device includes a vibrator radiator; a supporting plate parallel to and spaced apart from the vibrator radiator; a vibrator support provided between the vibrator radiator and the supporting plate; four vibrator radiating wires; and two differential feeding wires. The vibrator support includes an annular body and four supporting tabs extending outward from an outer periphery of the body and equally distributed in a circumference of the body. The supporting tab is perpendicularly connected to the supporting plate. Each differential feeding wire includes a differential feeding port and two feeding output ports that are respectively connected to two vibrator radiating wires that are not adjacent in the circumference of the body. The vibrator radiator, the supporting plate, the vibrator support, the vibrator radiating wire, and the differential feeding wire are manufactured separately and then assembled together, which simplifies the assembly and reduces assembly cost.

An radiating device includes a vibrator radiator; a supporting plate parallel to and spaced apart from the vibrator radiator; a vibrator support provided between the vibrator radiator and the supporting plate; four vibrator radiating wires; and two differential feeding wires. The vibrator support includes an annular body and four supporting tabs extending outward from an outer periphery of the body and equally distributed in a circumference of the body. The supporting tab is perpendicularly connected to the supporting plate. Each differential feeding wire includes a differential feeding port and two feeding output ports that are respectively connected to two vibrator radiating wires that are not adjacent in the circumference of the body. The vibrator radiator, the supporting plate, the vibrator support, the vibrator radiating wire, and the differential feeding wire are manufactured separately and then assembled together, which simplifies the assembly and reduces assembly cost.

An arrangement for modifying a printed circuit antenna of the type used in mobile communication devices includes introducing one or more discontinuities into a printed circuit pattern of the antenna so that it is not activated at undesired frequencies. Examples of discontinuities include localized narrowing the printed circuit strip, localized widening of the printed circuit strip and localized changing of the shape of the printed circuit strip.

An antenna arrangement includes a conductive element configured to resonate at and above a chosen electromagnetic radiation frequency corresponding to a fundamental resonant mode. The conductive element is folded to make coupling areas intended to shift one or more of the resonant frequencies of the higher resonant modes. Each coupling area is defined related to the set of resonant frequencies according to which the antenna is supposed to work, and is formed by positioning parts of the conductive element facing each other. The location, along the conductive element, of the parts of that conductive element intended to form a given coupling area as well as the length of these parts and as the width of the gap between them when the coupling area is formed, are determined so as to provide a given increase or decrease of the resonant frequency of a given resonant mode of the conductive element

An antenna arrangement includes a conductive element configured to resonate at and above a chosen electromagnetic radiation frequency corresponding to a fundamental resonant mode. The conductive element is folded to make coupling areas intended to shift one or more of the resonant frequencies of the higher resonant modes. Each coupling area is defined related to the set of resonant frequencies according to which the antenna is supposed to work, and is formed by positioning parts of the conductive element facing each other. The location, along the conductive element, of the parts of that conductive element intended to form a given coupling area as well as the length of these parts and as the width of the gap between them when the coupling area is formed, are determined so as to provide a given increase or decrease of the resonant frequency of a given resonant mode of the conductive element

An implantable electronic medical device has a device body and a header placed thereon, and includes a telemetry assembly for signal transmission to and/or from outside the body of a patient when the device is implanted, in particular for the wireless bidirectional communication. A transmit/receive antenna, which is physically formed of an elongated conductor and arranged in the region of the header and which is configured so as to have a form fit with the outer contour of at least a portion of the header, and is fixed thereby in the header, is at least largely assigned to the telemetry assembly. A first section of the conductor has a spring elastic design and forms a bracket or clamp. The bracket embraces a connector in the header. There is also described a transmit/receive antenna of a telemetry assembly of an implantable electronic medical device.

An implantable electronic medical device has a device body and a header placed thereon, and includes a telemetry assembly for signal transmission to and/or from outside the body of a patient when the device is implanted, in particular for the wireless bidirectional communication. A transmit/receive antenna, which is physically formed of an elongated conductor and arranged in the region of the header and which is configured so as to have a form fit with the outer contour of at least a portion of the header, and is fixed thereby in the header, is at least largely assigned to the telemetry assembly. A first section of the conductor has a spring elastic design and forms a bracket or clamp. The bracket embraces a connector in the header. There is also described a transmit/receive antenna of a telemetry assembly of an implantable electronic medical device.

A logging tool includes a mandrel having a tool axis, a first loop antenna including first windings wrapped about the mandrel, a second loop antenna co-located with the first loop antenna and including second windings wrapped about the mandrel, and a shield secured to the mandrel. The first loop antenna is in a first orientation and the first windings are wrapped at a first angle. The second loop antenna is in a second orientation opposite the first orientation and the second windings are wrapped at a second angle. The shield includes first slots overlapping and along the first loop antenna and second slots overlapping and along the second loop antenna. The first slots define a first trace angle with respect to the tool axis and different from the first angle. The second slots defines a second trace angle with respect to the tool axis and different from the first angle.

A logging tool includes a mandrel having an axis, a bobbin positioned about the circumference of the mandrel, and defining a first cross slot at a first slot angle and a second cross slot at a second slot angle opposite the first slot angle. The first and second cross slots intersect each other. The tool includes a first antenna in the first slot and including a first plurality of windings wrapped about the mandrel, a second antenna co-located with the first antenna and in the second slot, and an antenna shield secured to the tool mandrel and in each of the first and second slots. The first antenna is arranged in a first orientation and at a first winding angle. The second antenna is arranged in a second orientation and at a second winding angle.

A small cell base station includes a remote radio head that is configured for mounting on an aerial strand, a phased array antenna and a mechanical linkage. The phased array antenna is hung below the remote radio head via the mechanical linkage, and the mechanical linkage is configured to allow the phased array antenna to move relative to the remote radio head.