An example electronic device may include: a side member including a first conductive portion disposed through a first non-conductive portion and a second non-conductive portion and a second conductive portion disposed through the second non-conductive portion and a third non-conductive portion; a substrate disposed in the internal space of the housing and including a ground; at least one wireless communication circuit disposed on the substrate; a first switching circuit disposed in a first electrical path connecting the wireless communication circuit and a first point of the first conductive portion; a second switching circuit disposed in a second electrical path connecting the wireless communication circuit and a second point of the second conductive portion; a third switching circuit disposed in a third electrical path connecting the wireless communication circuit and a third point of the second conductive portion between the second point and the third non-conductive portion; and at least one processor configured to control at least one switching circuit among the first, second, and third switching circuits, wherein the second switching circuit is electrically connected to another—first point between the first point and the second non-conductive portion through another—first electrical path.

An example electronic device may include: a side member including a first conductive portion disposed through a first non-conductive portion and a second non-conductive portion and a second conductive portion disposed through the second non-conductive portion and a third non-conductive portion; a substrate disposed in the internal space of the housing and including a ground; at least one wireless communication circuit disposed on the substrate; a first switching circuit disposed in a first electrical path connecting the wireless communication circuit and a first point of the first conductive portion; a second switching circuit disposed in a second electrical path connecting the wireless communication circuit and a second point of the second conductive portion; a third switching circuit disposed in a third electrical path connecting the wireless communication circuit and a third point of the second conductive portion between the second point and the third non-conductive portion; and at least one processor configured to control at least one switching circuit among the first, second, and third switching circuits, wherein the second switching circuit is electrically connected to another—first point between the first point and the second non-conductive portion through another—first electrical path.

A projectile circuitry assembly for use in projectiles comprising a chassis defining a generally cylindrical a main body portion and further defining an interior cavity for containing one or more projectile components and further defining an antenna aperture through the body portion to expose the interior cavity. In various embodiments the projectile circuitry assembly comprises a plurality of circuit boards and a wrap antenna, the plurality of circuit boards and wrap antenna interconnected via an integrated flex-line to define a single unitary device without the use of a connector, the wrap antenna comprising one or more antenna elements defined on a flexible antenna substrate layer, wherein the plurality of circuit boards are positioned in the interior cavity and the wrap antenna is threaded through the antenna aperture and wrapped circumferentially about an exterior of the cylindrical wall of the body portion.

A device comprising a plurality of metallic conical radiators, said conical radiators substantially hollow having a vertex end and a base end, a first cylindrical portion disposed annularly about the base end of the conical portion, a metallic second cylindrical portion coupled to the vertex of the conical portion, said cylindrical portion having a threaded aperture, and an antenna feed coupled to the threaded aperture. The device may have patches disposed on a substrate as a one or multi-dimensional array. An RF feed may be coupled to the radiators.

A device comprising a plurality of metallic conical radiators, said conical radiators substantially hollow having a vertex end and a base end, a first cylindrical portion disposed annularly about the base end of the conical portion, a metallic second cylindrical portion coupled to the vertex of the conical portion, said cylindrical portion having a threaded aperture, and an antenna feed coupled to the threaded aperture. The device may have patches disposed on a substrate as a one or multi-dimensional array. An RF feed may be coupled to the radiators.

An RFID tag device is disclosed that is designed to operate on difficult substrates, such as dielectric surfaces with high loss, organic material surfaces, or metallic surfaces. The RFID tag device comprises an RFID antenna structure formed on one side of a thermoplastic substrate component with an RFID chip coupled to it in a roll to roll process. The substrate component is then deformed into a series of cavities with the RFID antenna structure within the cavities. Specifically, the RFID antenna structure is positioned fully on a top surface of the cavity, or positioned partially in a top and partially on an edge/bottom of the cavity.

An RFID tag device is disclosed that is designed to operate on difficult substrates, such as dielectric surfaces with high loss, organic material surfaces, or metallic surfaces. The RFID tag device comprises an RFID antenna structure formed on one side of a thermoplastic substrate component with an RFID chip coupled to it in a roll to roll process. The substrate component is then deformed into a series of cavities with the RFID antenna structure within the cavities. Specifically, the RFID antenna structure is positioned fully on a top surface of the cavity, or positioned partially in a top and partially on an edge/bottom of the cavity.

An electronic device may include a transceiver, first and second antennas, and a passive radio-frequency power distribution circuit. The distribution circuit may have a first port coupled to the transceiver, a second port coupled to the first antenna, and a third port coupled to the third antenna. The distribution circuit may include a transformer coupled between the ports. The transformer may have at least two intertwined inductors formed from conductive traces on a dielectric substrate. The intertwined inductors may be concentric about a common point. The intertwined inductors may extend from the common point to the second and third ports. The intertwined inductors may have a coil or spiral shape and may wind around the common point at least once. Intertwining the inductors may serve to minimize the lateral footprint of the distribution circuit in the device.

An electronic device may include a transceiver, first and second antennas, and a passive radio-frequency power distribution circuit. The distribution circuit may have a first port coupled to the transceiver, a second port coupled to the first antenna, and a third port coupled to the third antenna. The distribution circuit may include a transformer coupled between the ports. The transformer may have at least two intertwined inductors formed from conductive traces on a dielectric substrate. The intertwined inductors may be concentric about a common point. The intertwined inductors may extend from the common point to the second and third ports. The intertwined inductors may have a coil or spiral shape and may wind around the common point at least once. Intertwining the inductors may serve to minimize the lateral footprint of the distribution circuit in the device.

A radar apparatus includes an antenna device including a first transmitting antenna, a second transmitting antenna, and a receiving antenna, a transceiver configured to transmit a transmission signal through one of the first transmitting antenna and the second transmitting antenna and receive a reflection signal reflected on an object through the receiving antenna, and a controller configured to process the reflection signal received through the receiving antenna to obtain information on the object, wherein the controller controls the transceiver to receive the reflection signal through the second transmitting antenna and the receiving antenna when the transmission signal is transmitted through the first transmitting antenna.