Provided is a wearable device including an annular metal shell and a circuit board. The circuit board is disposed in the annular metal shell, and includes a clearance zone and a tracing zone. The clearance zone includes an antenna feeding portion, and the tracing zone includes electronic elements, a metal circuit, and an antenna grounding portion. The antenna feeding portion is coupled to the electronic elements and the metal circuit, and the antenna feeding portion and the antenna grounding portion are coupled to the annular metal shell, such that the antenna feeding portion, the electronic elements, and the metal circuit jointly resonate at a frequency band.

Disclosed herein includes a wireless device including a first antenna configured to perform wireless communication, a second antenna configured to perform wireless communication, and a parasitic antenna. The first antenna may have a feed connected to a first impedance tuner that is connected to a first ground planes. The second antenna may have a feed connected to a second impedance tuner. The parasitic antenna may be disposed between the first and second antennas, with a feed connected to a third impedance tuner that is connected to a second ground plane. The first, second and third impedance tuners may be adjusted to configure the first, second and parasitic antennas to achieve a same resonant frequency.

A radar assembly includes a hollow drum and an antenna holding structure located inside the hollow drum so that the hollow drum can rotate around the antenna holding structure. An antenna is connected to the antenna holding structure and located inside the hollow drum so that the hollow drum can rotate around the antenna. The antenna holding structure is connected to a base frame and to which the hollow drum is connected via at least one axle so that the hollow drum can rotate around the antenna holding structure while the antenna holding structure and antenna remain stationary. A handle is connected to the base frame so that a user can direct the antenna towards a surface of interest which is to be radiated and can then roll the hollow drum over the surface while maintaining the antenna in a user selected orientation.

An antenna assembly for use with a medical implant includes an antenna that defines at least one turn and an electromagnetic shield.

A wearable electronic device is described. The wearable electronic device includes two communications antennae. A first antenna of the two is a current-carrying antenna electrically and physically connected to a printed circuit board of the wearable electronic device and housed in a first portion of a housing that is configured for mounting on a person's skin. A second antenna of the two is a scatterer antenna physically connected to an interior surface of a second portion of the housing and configured to overlap a portion of the current-carrying antenna. The second portion of the housing faces away from the person's skin when the wearable device is mounted on the person's skin. Current from the current-carrying antenna is induced in the scatterer antenna to enable communications between the wearable electronic device and one or more other electronic devices.

An apparatus includes an eyeglass frame, a first antenna, a second antenna, and a parasitic element. The eyeglass frame can include at least one rim. The first antenna can be attached to the eyeglass frame. The second antenna can be attached to the eyeglass frame. The second antenna can be disposed on a first side of the at least one rim. The parasitic element can be attached to the eyeglass frame. The parasitic element can be on a second side of the at least one rim. The second side of the at least one rim can be opposite from the first side. A distance from the first antenna to the second antenna can be greater than a distance from the first antenna to the parasitic element. The distance from the first antenna to the second antenna can be greater than a distance from the second antenna to the parasitic element.

Embodiments relate to a sensor node communication system that determines the presence of an object. The system includes man-portable nodes that communicate via a self-organizing LAN. Each node includes a control circuit that has multiple cores, multithreading, and/or parallel processing. The control circuit establishes the LAN, captures an image, determines a presence of a predetermined object in the image using a machine learning algorithm, generates a first notification when presence of the predetermined object is determined, and generates a second notification when the presence is not determined. The control circuit detects an electromagnetic environment, determines unused frequency bands, and adapts a radio working parameter to broadcast in the unused frequency band. Determining the unused frequency bands includes the use of a spectrum sensing method. The control circuit detects an electromagnetic environment, determines unused frequency bands, and adapts a radio working parameter to broadcast in unused frequency bands.

An electronic device and a wearable device are provided. The electronic device includes a cover plate, a middle frame and a circuit board. The middle frame is provided with a mounting cavity; the middle frame is provided with a mating surface; the middle frame includes an antenna exposed from the mating surface; and the cover plate is stacked on the mating surface and covers the antenna and the mounting cavity. The circuit board is arranged in the mounting cavity and is electrically connected to the antenna. Compared with an antenna in the form of flexible circuit board, the arrangement of the antenna herein can reduce an overall thickness of the electronic device, and can improve the anti-interference and anti-shielding performance of the antenna to enhance the communication performance of the electronic device.

A wearable antenna is described, for wirelessly receiving sensor data generated by an implantable sensor device implanted in a uterus, the wearable antenna, in use, extending around the waist of the wearer's body, and having a downwardly extending portion for location at the front of the wearer's body. In this way, an improved electromagnetic interaction between the wearable antenna and the implantable sensor can be achieved. Further, the wearable antenna may have an undulating shape around at least a portion of the wearer's waist, to permit expansion and contraction of the wearable antenna about the wearer's waist.

A wearable device is provided. The wearable device includes a housing, an input member disposed on a lateral surface of the housing and including an outer lateral surface including a conductive portion and a non-conductive portion, a metal member disposed inside the housing and in contact with the conductive portion of the outer lateral surface, a printed circuit board (PCB) disposed on the metal member, a patch antenna including a conductive patch disposed on a surface of the PCB facing the input member at a location corresponding to the non-conductive portion, a wireless communication circuit electrically connected to the PCB and the patch antenna, and a processor connected to the metal member. The wireless communication circuit transmits a signal by feeding power to the patch antenna, and the processor acquires user biometric information through the metal member and the conductive portion of the input member.