The invention provides a stacked structure of circuit boards applied to a data storage device. The stacked structure comprises a main circuit board and a slave circuit board. The main circuit board comprises a controller, a plurality of flash memories, a first connector, and a first transmission interface. The slave circuit board comprises an operation management chip, a second connector, and a second transmission interface. The operation management chip comprises a microprocessor and a network communication element. The slave circuit board is stacked on the main circuit board, and connected to the first connector of the main circuit board via the second connector. When the slave circuit board receives a specific operation instruction, the microprocessor of the slave circuit board will transmit the specific operation instruction to the electronic apparatus via the second transmission interface, the electronic apparatus executes a corresponding operation according to the specific operation instruction.

A device that includes a board, a package and a patch substrate. The board includes a cavity. The package is coupled to a first side of the board. The package includes a substrate and an integrated device coupled to the substrate. The integrated device is located at least partially in the cavity of the board. The patch substrate is coupled to a second side of the board. The patch substrate is located over the cavity of the board. The patch substrate is configured as an electromagnetic interference (EMI) shield for the package.

Provided is a proximity sensor that can limit degradation in voltage resistance. A proximity sensor includes: a housing; a coil portion that is accommodated in one end of the housing; a clamp portion that is connected to the other end of the housing; a substrate which is accommodated inside the housing and the clamp portion, and on which a circuit electrically connected to the coil portion is mounted; a shield that covers a part of the substrate located on a side of the housing; and a resin portion which is arranged inside the housing and the clamp portion, and covers at least a part of the substrate. The shield has an extension portion which extends to an inside of the clamp portion and covers at least a part of the circuit located inside the clamp portion.

An electronic device and a shielding film are disclosed herein. The electronic device includes a printed circuit board and at least one electrical component mounted on the printed circuit board. The shielding film is disposed on at least a part of the printed circuit board to block electromagnetic waves generated by the printed circuit board and/or the electronic component. The shielding film includes a plurality of layers, and is attached to at least part of the printed circuit board and contacting an upper side surface of the electronic component, wherein at least part of the shielding film includes a nano-conductive fiber and is electrically connected with a ground part of the printed circuit board through the nano-conductive fiber.

A sensor unit includes a plurality of bus bars connected to a plurality of switch modules, a terminal block that integrally links the bus bars, and a plurality of magnetoelectric conversion parts that detect currents flowing through the bus bars. Embedded parts of the bus bars embedded in the terminal block are aligned in a first predefined direction with spaces therebetween. The magnetoelectric conversion parts are provided in the terminal block such that they face the embedded parts. Extension parts, extending in the first predefined direction, of any two embedded parts adjacent to each other in a predefined direction adjoin each other in a second predefined direction that intersects the first predefined direction.

Techniques and mechanisms for coupling packaged devices with a socket device. In an embodiment, the socket device comprises a socket body structure and conductors extending therethrough. A pitch of the conductors is in a range of between 0.1 millimeters (mm) and 3 mm. First and second metallization structures also extend, respectively, from opposite respective sides of the socket body structure. In the socket body structure, a conductive shield structure, electrically coupled to the first and second metallization structures, substantially extends around one of the conductors. For each of the first and second metallization structures, a vertical span of the metallization structure is in a range of between 0.05 mm and 2.0 mm, a portion of a side of the metallization structure forms a respective corrugation structure, and a horizontal span of the portion is at least 5% of the vertical span of the metallization structure.

An electromagnetic tracking system includes a magnetic transmitter configured to output magnetic fields, a receiver responsive to the magnetic fields, an electronics assembly having conductive elements that cause distortion to the magnetic fields, and an output mechanism configured to output a position of the receiver relative to the magnetic transmitter, wherein the magnetic transmitter has at least one winding disposed around a hollow ferromagnetic core comprised of conductive material through which current is made to flow by the electronics, wherein the electronics assembly is at least partially contained within the hollow portion of the hollow ferromagnetic core. Methods of manufacturing include shaping walls into a hollow shell to surround an electronics assembly, covering the hollow shell with ferromagnetic material, inserting the wrapped hollow shell into a plastic bobbin, and winding the plastic bobbin with coil wire to produce three orthogonal windings.

An electronic device module includes: a substrate; at least one electronic device mounted on a first surface of the substrate; a shielding wall mounted on the first surface of the substrate; a sealing portion disposed on the first surface of the substrate such that the at least one electronic device and the shielding wall are embedded in the sealing portion; and a shielding layer disposed on one surface of the sealing portion. At least a portion of the sealing portion is disposed externally of the shielding wall. The shielding wall and the shielding layer are formed of different materials.

An electronic device includes a housing, a first printed circuit board (PCB) provided within the housing, a second PCB provided within the housing, and a battery. The second PCB is separate and distinct from the first PCB and is communicatively coupled to the first PCB. The battery is located in a space separating the first PCB and the second PCB. The battery is configured to provide power to the first PCB and the second PCB.

An electromagnetic-wave shielding sheet is an electromagnetic-wave shielding sheet used to form an electronic component-mounted substrate, the electronic component-mounted substrate including an electromagnetic-wave shielding layer covering at least a part of a step part and an exposed surface of a substrate, in which the electromagnetic-wave shielding sheet is a laminate including a cushion layer and a conductive layer, the conductive layer is an isotropic conductive layer containing a binder resin and a conductive filler, a thickness of the conductive layer is 8 to 70 μm, and a content of the conductive filler in a region on a side opposite to a cushion layer side in the conductive layer is larger than that in a region on the cushion layer side in the conductive layer.