Provided is an LC resonant antenna including: an inductor layer provided with a coil-shaped inductor; and a capacitor layer laminated on the inductor layer in a direction of an axis along a coil center of the inductor. The capacitor layer includes a capacitor connected to the inductor. The capacitor includes a pair of electrode plates arranged in parallel at a distance from each other in a laminating direction.

Provided is an LC resonant antenna including: an inductor layer provided with a coil-shaped inductor; and a capacitor layer laminated on the inductor layer in a direction of an axis along a coil center of the inductor. The capacitor layer includes a capacitor connected to the inductor. The capacitor includes a pair of electrode plates arranged in parallel at a distance from each other in a laminating direction.

An antenna arrangement (6) for an external watch part (2) of a timepiece. The antenna arrangement is formed of a technical embroidery, which includes an embroidered structure of insulating wires or natural fibres (10) and at least one conductive wire (12) embroidered so as to produce a fine coil integrated in the embroidered structure of insulating wires or natural fibres. The conductive wire is connected to a radiofrequency integrated circuit (8).

An antenna arrangement (6) for an external watch part (2) of a timepiece. The antenna arrangement is formed of a technical embroidery, which includes an embroidered structure of insulating wires or natural fibres (10) and at least one conductive wire (12) embroidered so as to produce a fine coil integrated in the embroidered structure of insulating wires or natural fibres. The conductive wire is connected to a radiofrequency integrated circuit (8).

Blade antenna suitable for use in a wireless local area network, comprising at least one blade antenna unit and preferably two blade antenna units wherein each unit comprises: a ground plane, a first blade structure which is mounted substantially perpendicular onto the ground plane, wherein the ground plane and first blade structure are at least partially made of an electrically conductive material and are electrically insulated from each other, thereby forming a blade antenna, a body of dielectric material in which the blade structure at least partially is embedded and which functions as a lens structure for electromagnetic waves received or

Disclosed is an electronic device including a housing, a first plate positioned on a front surface of the housing, a second plate positioned on a rear surface of the housing, an antenna radiator interposed between the first plate and the second plate, and a wireless communication circuit connected to the antenna radiator and processing a signal in a specific frequency band. The antenna radiator includes at least one conductive fabric layer having a resistance characteristic suitable for transmitting or receiving the signal in the specific frequency band, and the at least one conductive fabric layer includes a fabric that is plated with at least one metal.

Systems and methods presented herein provide for elastomeric and flexible cables. One cable includes a first insulator extruded as a tube. The cable also includes an elastomeric conductor comprising conductive particles embedded in a polymer. The elastomeric conductor is extruded with the elastomeric insulator through a conduit of the tube. Other cables include flexible wires extruded with elastomeric tubes. In some embodiments, the cables are configured with stay cords that limit a length of stretching in the cable.

Systems and methods presented herein provide for elastomeric and flexible cables. One cable includes a first insulator extruded as a tube. The cable also includes an elastomeric conductor comprising conductive particles embedded in a polymer. The elastomeric conductor is extruded with the elastomeric insulator through a conduit of the tube. Other cables include flexible wires extruded with elastomeric tubes. In some embodiments, the cables are configured with stay cords that limit a length of stretching in the cable.

Flexible antennas for harvesting electromagnetic energy are described. The flexible antenna may be a far field antenna and may comprise a flexible substrate, a first metal layer disposed on one side of the flexible substrate, and a second metal layer disposed on an opposite side of the flexible substrate. The first and second metal layers may be connected through one or more vias. The first metal layer may be sized to capture electromagnetic energy at a frequency in an ISM band.

An antenna apparatus includes an electrically conductive section having peripheral edges, an antenna element coupled to the electrically conductive section, which transmits or receives electromagnetic signals, and an electromagnetic absorbing carbon material component. The carbon material component is generally disposed adjacent to the electrically conductive section, and includes a border region extending beyond the peripheral edges of the electrically conductive section. The carbon material component can be constructed of a carbon fiber fabric in which the carbon fibers are arranged to increase the effective signal to noise ratio of the antenna apparatus and enhance antenna performance without increasing the baseline power consumption level. The carbon fibers can be coated with silicone to insulate them externally while enhancing their lengthwise conductivity.