Provided is a structure including a first conductor plane (101); a second conductor plane (102); a first transmission line (104) that is formed in a layer different from the first conductor plane (101) and the second conductor plane (102); a second transmission line (105) that is disposed so as to face the second conductor plane (102) in a layer opposite to the first transmission line (104) with respect to the second conductor plane (102); a first conductor via (103) that connects one end of the first transmission line (104) with the first conductor plane (101); a second conductor via (106) that connects another end of the first transmission line (104) with one end of the second transmission line (105); and a slit (107) that is formed on the second conductor plane (102).

Power amplifier systems including power amplifier modules (PAMs) and electromagnetic bandgap (EBG) isolation structures are disclosed. In embodiments, the power amplifier system includes a printed circuit board (PCB) and a PAM mounted to the PCB in an inverted orientation. The PCB has a PCB frontside on which a PAM mount region is provided, and radio frequency (RF) input and output bondpads. The PAM includes a topside input/output interface having RF input and output terminals electrically coupled to the RF input and output pads, respectively. The power amplifier system further includes a first EBG isolation structure containing a first grounded EBG cell array, at least a portion of which is located within or beneath the PAM mount region.

The present application relates to an electromagnetic band-gap, a directional antenna including same, and a use thereof. The electromagnetic band-gap structure and the directional antenna including same, of the present application, are lightweight and small in size, and can have excellent directivity. In addition, the electromagnetic band-gap structure and the directional antenna including same can be used for aviation electronic equipment and portable measurement equipment.

The present disclosure relates to an electronic device, and the electronic device may include a circuit board provided within a main body of the electronic device, on which a conductive layer made of a conductive material and a dielectric layer made of an insulating material are alternately laminated; at least one or more patch antennas disposed on the circuit board; a core layer located at a central portion inside the circuit board, and configured with any one of the dielectric layers; a ground layer disposed below the core layer; and an EBG structure located inside the circuit board in a symmetrical shape at the top and bottom with respect to the core layer, and the EBG structure restricts operating frequency signals radiated from the respective patch antennas from being interfered with each other.

A signal isolation device includes at least one electromagnetic band-gap unit. The at least one electromagnetic band-gap unit includes a substrate, a metal foil main body, and a plurality of T-shaped metal foil features. The metal foil main body is disposed on the substrate, and the metal foil main body is square. The T-shaped metal foil features is disposed on the substrate and extending from a periphery of the metal foil main body. The T-shaped metal foil features are in a rotational symmetry around a center of the metal foil main body.

An electronic device according to various embodiments may include a housing, an antenna structure positioned in the housing, and a wireless communication circuit. The antenna structure may include a first conductive layer including a first opening, a second conductive layer positioned in parallel with the first conductive layer, and including a second opening which overlaps at least in part with the first opening when the first conductive layer is seen from above, a third conductive layer positioned in parallel with the first conductive layer and interposed between the first conductive layer and the second conductive layer, a first insulating layer interposed between the first conductive layer and the third conductive layer, a second insulating layer interposed between the second conductive layer and the third conductive layer, a first conductive plate electrically separated from the first conductive layer and disposed within the first opening, a second conductive plate electrically separated from the second conductive layer and disposed within the second opening, a first conductive via electrically coupled between the first conductive plate and the third conductive layer through the first insulating layer, and a second conductive via electrically coupled between the second conductive plate and the third conductive layer through the second insulating layer. The wireless communication circuit may be configured to transmit or receive a signal having a frequency between 3 Giga Hertz (GHz) and 100 GHz and is electrically coupled to the antenna structure. Various embodiments may be possible.

An electronic component package structure and an electronic device are provided. The electronic component package structure includes at least: a substrate having a set attachment area for attaching an electronic component; a conductive lid having a top and a sidewall that extends toward the substrate, where one side of the sidewall close to the substrate has a bonding end, where the bonding end bonds the conductive lid to the substrate by using a non-conductive adhesive, and the conductive lid bonded to the substrate encloses the attachment area and forms a shielding space over the attachment area; and the non-conductive adhesive is located between the substrate and the bonding end, and has a dielectric constant not less than 7 and a coating thickness not greater than 0.07 millimeters (mm). With the present invention, an Electromagnetic Interference (EMI) shielding effect of the shielding space can be improved.

An electronic circuit includes plural individual electronic circuits arranged, in which each of the plural individual electronic circuits has a first conductor column that is connected to a ground of a first layer which is any one of plural conductor layers sequentially stacked in a separated state and extends in a stacking direction, a conductor line that is connected to the conductor column to extend in a band shape in a second layer different from the first layer which is any one of the plural conductor layers, and of which an end portion separated from the conductor column is an open end, and a second conductor column that is connected to the conductor line, is not connected to the ground, and extends in the stacking direction, and each of a first individual electronic circuit and a second individual electronic circuit adjacent to each other among the plural individual electronic circuits has at least a pair of the second conductor columns, which are formed at adjacent positions without interposing any one of the conductor lines of the first individual electronic circuit and the second individual electronic circuit between the pair of the second conductor columns.

A printed circuit board including a series-wound inductor and two capacitors to reduce the susceptibility of a printed circuit board to simultaneous switching noise includes a ground layer; a power layer defining a slot loop to isolate a metal plate within, and a via hole coupled between the metal plate and the ground layer. An electronic device with the printed circuit board is also disclosed.

The present disclosure relates generally to radio engineering, and for example, to high-rate wireless data transfer between different printed circuit boards or between parts of the same printed circuit board. The technical result is easier fabrication, smaller dimensions, lower losses at high frequencies and improved performance. According to the disclosure, a wireless data transfer system comprises: two printed circuit boards separated by an air gap, between which a transverse electromagnetic (TEM) mode waveguide is formed, wherein each printed circuit board includes a converter structure configured to: perform conversion between the signal transmission line mode and TEM mode in the waveguide, connected to an RF component; wherein the converter structure includes: an antenna, a signal transmission line between the antenna and the RF component, and at least one reflector configured to provide directive propagation of the TEM mode in the waveguide; wherein the width of the air gap between the printed circuit boards does not exceed λ/4, where λ is the wavelength of the transmitted signal.