A ferrite sheet includes acicular ferrite powder, and has a uniaxially-oriented magnetic direction. The ferrite sheet is capable of remarkably increasing magnetic permeability and saturation magnetization, and accordingly is capable of remarkably improving the power efficiency of an electronic device by minimizing magnetic field leakage when being applied to a shielding sheet.

Various embodiments of a wireless connector system are described. The system has a transmitter module and a receiver module that are configured to wirelessly transmit electrical energy and/or data via near field magnetic coupling. The wireless connector system is designed to increase the amount of wirelessly transmitted electrical power over a greater separation distance. The system is configured with various sensing circuits that alert the system to the presence of the receiver module to begin transfer of electrical power as well as undesirable objects and increased temperature that could interfere with the operation of the system. The wireless connector system is a relatively small foot print that is designed to be surface mounted.

Disclosed are an Electromagnetic Interference shielding film, a circuit board and a preparation method of the electromagnetic Interference shielding film. The electromagnetic Interference shielding film includes: a first shielding layer, a second shielding layer, an adhesive film and multiple convex particles, wherein the first shielding layer includes a first surface and a second surface opposite to each other; the second surface is a flat surface; the multiple convex particles are adhered on the second surface of the first shielding layer; the second shielding layer is disposed on the second surface of the first shielding layer and covers the multiple convex particles, thereby forming a protrusion portion at a position corresponding to the convex particles on an outer surface of the second shielding layer and forming a gentle portion at other positions; and the adhesive film is disposed on the outer surface of the second shielding layer.

An electronic component includes a board, a surface mount device, a nonmagnetic resin layer, a metal shield layer, and a magnetic shield layer. The board includes first and second principal surfaces facing each other, and a magnetic body layer. The surface mount device is mounted on the first principal surface of the board. The nonmagnetic resin layer covers the surface mount device. The metal shield layer covers the nonmagnetic resin layer. The magnetic shield layer covers an entire or substantially an entire surface of the metal shield layer.

A method of preparing a MnB-based magnetic material, the method including the steps of preparing a mixture including manganese oxide and boron, and heat-treating the mixture under an inert atmosphere, a MnB-based magnetic material prepared thereby, and a material absorbing or shielding electromagnetic waves, or a semiconductor, electronic, communication, or display device including the MnB-based magnetic material, are provided.

Disclosed are an Electromagnetic Interference shielding film, a circuit board and a preparation method of the electromagnetic Interference shielding film. The electromagnetic Interference shielding film includes: a first shielding layer, a second shielding layer, an adhesive film and multiple convex particles, wherein the first shielding layer includes a first surface and a second surface opposite to each other; the second surface is a flat surface; the multiple convex particles are adhered on the second surface of the first shielding layer; the second shielding layer is disposed on the second surface of the first shielding layer and covers the multiple convex particles, thereby forming a protrusion portion at a position corresponding to the convex particles on an outer surface of the second shielding layer and forming a gentle portion at other positions; and the adhesive film is disposed on the outer surface of the second shielding layer.

Various embodiments of a wireless connector system are described. The system has a transmitter module and a receiver module that are configured to wirelessly transmit electrical energy and/or data via near field magnetic coupling. The wireless connector system is designed to increase the amount of wirelessly transmitted electrical power over a greater separation distance. The system is configured with various sensing circuits that alert the system to the presence of the receiver module to begin transfer of electrical power as well as undesirable objects and increased temperature that could interfere with the operation of the system. The wireless connector system is a relatively small foot print that is designed to be surface mounted.

Various embodiments of a wireless connector system are described. The system has a transmitter module and a receiver module that are configured to wirelessly transmit electrical energy and/or data via near field magnetic coupling. The wireless connector system is designed to increase the amount of wirelessly transmitted electrical power over a greater separation distance. The system is configured with various sensing circuits that alert the system to the presence of the receiver module to begin transfer of electrical power as well as undesirable objects and increased temperature that could interfere with the operation of the system. The wireless connector system is a relatively small foot print that is designed to be surface mounted.

An electronic component includes a wiring substrate, surface mount devices mounted on a front surface of the wiring substrate, and a shield plate fixed on a side adjacent to top surfaces of the surface mount devices. The shield plate includes a magnetic ceramic sintered sheet and a first metal film. The magnetic ceramic sintered sheet includes a first main surface and a second main surface. The first metal film is disposed on the first main surface of the magnetic ceramic sintered sheet.

Internally-shielded microelectronic packages having increased resistances to electromagnetic cross-coupling are disclosed, as are methods for fabricating such microelectronic packages. In embodiments, the internally-shielded microelectronic package includes a substrate having a frontside and a longitudinal axis. A first microelectronic device is mounted to the frontside of the substrate, while a second microelectronic device is further mounted to the frontside of the substrate and spaced from the first microelectronic device along the longitudinal axis. An internal shield structure includes or consists of a shield wall, which is positioned between the first and second microelectronic devices as taken along the longitudinal axis. The internal shield structure is at least partially composed of a magnetically-permeable material, which decreases electromagnetic cross-coupling between the first and second microelectronic devices during operation of the internally-shielded microelectronic package.