An ingestible device comprising a capsule, a camera, an antenna, and a propulsion component id disclosed. The camera can capture images of various in vivo environments as the ingestible device traverses the gastrointestinal tract, and these images can be wirelessly transmitted to an electronic device located outside of the living body. The images may be transmitted to the electronic device for review by an operator responsible for controlling the ingestible device.

The present disclosure relates to a display apparatus including a display panel, a bezel surface formed on a boundary of the display panel, and an antenna located on the bezel surface, wherein the antenna includes a composite right left handed (CRLH) structure including a series inductor, a series capacitor, a parallel inductor, and a parallel capacitor.

The present disclosure relates to a display apparatus including a display panel, a bezel surface formed on a boundary of the display panel, and an antenna located on the bezel surface, wherein the antenna includes a composite right left handed (CRLH) structure including a series inductor, a series capacitor, a parallel inductor, and a parallel capacitor.

Some embodiments include a dipolar antenna system to electrically power an implantable miniature device and/or to stimulate bioelectrically excitable tissue. Other related systems and methods are also disclosed.

Some embodiments include a dipolar antenna system to electrically power an implantable miniature device and/or to stimulate bioelectrically excitable tissue. Other related systems and methods are also disclosed.

An in-the-ear hearing device includes: a microphone configured to receive an audio signal; a signal processor configured to process the audio signal for compensating a hearing loss; a wireless communication unit being connected to the signal processor; a feeding network; a hearing device shell accommodating the microphone and the signal processor; a face plate positioned at the hearing device shell; and an antenna for electromagnetic field emission and electromagnetic field reception, the antenna coupled with the wireless communications unit, wherein the antenna has a first end, and wherein the feeding network is configured to feed the antenna via the first end of the antenna; wherein the antenna extends through the face plate at a first position; at least a part of the antenna extending from the faceplate being arch-shaped; and wherein a second end of the antenna is an electrically open end, or is coupled to a ground potential.

An in-the-ear hearing device includes: a microphone configured to receive an audio signal; a signal processor configured to process the audio signal for compensating a hearing loss; a wireless communication unit being connected to the signal processor; a feeding network; a hearing device shell accommodating the microphone and the signal processor; a face plate positioned at the hearing device shell; and an antenna for electromagnetic field emission and electromagnetic field reception, the antenna coupled with the wireless communications unit, wherein the antenna has a first end, and wherein the feeding network is configured to feed the antenna via the first end of the antenna; wherein the antenna extends through the face plate at a first position; at least a part of the antenna extending from the faceplate being arch-shaped; and wherein a second end of the antenna is an electrically open end, or is coupled to a ground potential.

Introduced here is an ingestible device comprising a capsule, a camera, an antenna, and a propulsion component. The camera can capture images of various in vivo environments as the ingestible device traverses the gastrointestinal tract, and these images can be wirelessly transmitted to an electronic device located outside of the living body. The images may be transmitted to the electronic device for review by an operator responsible for controlling the ingestible device.

Introduced here is an ingestible device comprising a capsule, a camera, an antenna, and a propulsion component. The camera can capture images of various in vivo environments as the ingestible device traverses the gastrointestinal tract, and these images can be wirelessly transmitted to an electronic device located outside of the living body. The images may be transmitted to the electronic device for review by an operator responsible for controlling the ingestible device.

A multi-frequency antenna includes a ground layer, at least one antenna unit and at least one antenna network. The antenna unit has its one end electrically connected to the ground layer and its other end electrically connected to the antenna network for generating at least one first resonance frequencies. The antenna network includes at least one feeding circuit, and at least one resonance unit. Each resonance unit includes at least one resonant segment. Each resonant segment is electromagnetically coupled with the adjacent ground layer to generate at least one second resonance frequency. Thus, the multi-frequency antenna is capable of generating multiple different resonance frequencies.