The disclosure relates to methods for direct ink jet printing of printed circuits' infrastructure. Specifically, the disclosure relates to methods for direct inkjet printing of heatdissipation elements and sockets for use in printed circuit boards (PCBs), flexible printed circuits (FPCs) and high-density interconnect (HDI) printed circuits.

A laminated sheet includes a sheet-shaped inductor including a plurality of wirings and a magnetic layer embedding the plurality of wirings, and a mark formable layer disposed on one surface in a thickness direction of the inductor.

A circuit board includes a glass substrate having a first surface and a second surface facing away from the first surface; a first coil wiring pattern formed on the first surface and a second coil wiring pattern formed on the second surface, the first and second coil wiring patterns constituting part of a coil; a through hole extending through a predetermined portion of the glass substrate from an end of the first coil wiring pattern to an end of the second coil wiring pattern; a through hole inner conductive surface formed on the inner side of the through hole, the first and second coil wiring patterns and the through hole inner conductive surface constituting the coil wound around a direction perpendicular to an axis of the through hole and to a direction in which the first and second coil wiring patterns extend.

A rotation sensor, including: (i) a substrate having a top surface and an interior bottom surface; (ii) an electrode module positioned on the top surface of the substrate and including a first set of electrodes configured to generate a bulk acoustic wave directly into the substrate, wherein at least a portion of the bulk acoustic wave is transduced into a shear wave upon reflection on the interior bottom surface of the substrate without use of a reflector, and a second set of electrodes configured to detect the shear wave; and (iii) a controller in communication with the first set and second set of electrodes and configured to determine, based on the detected shear wave, an effect of Coriolis force on the sensor.

A semiconductor package of an embodiment includes a wiring substrate, a semiconductor chip provided on an upper surface of the wiring substrate, a sealing resin covering surfaces of the wiring substrate and the semiconductor chip, an infrared reflection layer containing any of aluminum, aluminum oxide, and titanium oxide, and an external terminal provided on a lower surface of the wiring substrate. The wiring substrate is electrically connectable with a printed wiring board through the external terminal. The infrared reflection layer is provided to the sealing resin on an upper side of a surface of the semiconductor chip on a side opposite to an upper surface of the wiring substrate.

A printed wiring board includes: a first insulating layer having a first surface and a second surface opposite from the first surface; a second insulating layer stacked on the first surface of the first insulating layer; and a conductor wiring interposed between the first insulating layer and the second insulating layer. The first insulating layer contains a liquid crystal polymer. The second insulating layer contains a cured product of a thermosetting composition, containing an inorganic filler and a thermosetting component, and a fibrous base member. A temperature, at which a decrease in the mass of the second insulating layer that has had its temperature increased at a temperature increase rate of 10° C./min from an initial-state temperature of 25° C. reaches 5% of its initial-state mass, is equal to or higher than 355° C.

Disclosed herein is an electronic component that includes a first conductive layer including a lower electrode and a first inductor pattern, a dielectric film that covers the lower electrode, an upper electrode laminated on the lower electrode through the dielectric film, an insulating layer that covers the first conductive layer, dielectric film, and upper electrode, and a second conductive layer formed on the insulating layer and including a second inductor pattern. The first and second inductor patterns are connected in parallel through via conductors penetrating the insulating layer.

Disclosed herein a thin film capacitor that includes a lower electrode layer, an upper electrode layer, and a dielectric layer disposed between the lower electrode layer and the upper electrode layer. The dielectric layer has a through hole. The upper electrode layer has a connection part connected to the lower electrode layer through the through hole and an electrode part insulated from the connection part by a slit. A surface of the lower electrode layer that contacts the connection part through the through hole includes an annular area positioned along an inner wall surface of the through hole and a center area surrounded by the annular area. The annular area is lower in surface roughness than the center area.

A camera module of an embodiment may comprise: a first holder in which a filter is mounted; a lens barrel that is provided to be vertically movable in a first direction with respect to the first holder; a lens operating device that comprises a terminal and moves the lens barrel in the first direction; a first circuit board that is disposed under the first holder and on which an image sensor is mounted; a soldering portion for electrically connecting the terminal of the lens operating device to the first circuit board; and a coupling reinforcement portion that is disposed to face the soldering portion and couples the lens operating device and the first circuit board.

A flexible circuit board and a display panel are provided. The flexible circuit board includes a base body and a protective layer disposed on the base body. The protective layer includes a glue layer, a first cover layer, a patterned function layer, and a second cover layer sequentially stacked on the base body. The patterned function layer includes a frame and a plurality of bendable components disposed in the frame. The bendable components are arranged in the frame at intervals, and an arrangement direction of the bendable components is consistent with a bent direction of the flexible circuit board.