A detection device includes a sensor substrate provided with a plurality of photosensors, a control board provided with a control circuit configured to control the photosensors, and a flexible printed circuit board provided with wiring configured to electrically couple the sensor substrate to the control board. The flexible printed circuit board is provided with a plurality of cutting indication lines for changing a length between the sensor substrate and the flexible printed circuit board.

A method of producing electronic components each including a substrate-type terminal and a device connected to the substrate-type terminal including a substrate body with first and second principal surfaces opposite to each other and an electrode configured to be connected to the device on the first principal surface, wherein the device is disposed on the first principal surface, includes forming grooves in a substrate from one of the first and second principal surfaces of the substrate such that the substrate is divided into the substrate-type terminals, the grooves each having a depth less than a thickness of the substrate, cutting the substrate from another principal surface opposite to the principal surface of the substrate body such that the grooves penetrate through the substrate in a thickness direction thereof, and mounting the device on each of the first principal surfaces.

A method of producing electronic components each including a substrate-type terminal and a device connected to the substrate-type terminal is performed such that the substrate-type terminal includes a substrate body including a rectangular or substantially rectangular first principal surface extending in first and second directions perpendicular or substantially perpendicular to each other. The device is disposed on the first principal surface. The method includes supporting a substrate that is to become an assembly in which the plurality of substrate-type terminals are arranged in a matrix using a first support member, cutting the substrate supported by the first support member into the plurality of substrate-type terminals, and mounting the device on the first principal surface of the substrate body of each of the plurality of substrate-type terminals obtained by cutting.

A curved display device and method for manufacturing the same is provided. The method for manufacturing a curved display device may include providing a display panel, a plurality of signal transfer elements, and a plurality of printed circuit boards, connecting one end of each of the signal transfer elements to the display panel and connecting the other end of each of the signal transfer elements to one of the printed circuit boards, on which one or more division guide portions are formed, dividing each of the printed circuit board into a plurality of sub printed circuit boards through cutting of the division guide portions; and bending the display panel connected to the sub printed circuit boards so that the display panel has a curvature.

Provided is a master printed circuit board (PCB). The master PCB includes panels defined by grooves cut in the master PCB, the grooves separating one panel from another. A final PCB is formable via use of one or more jumpers, wherein the jumpers are configured to extend across at least one of the grooves to electrically connect one panel to another panel. The electrically connected panels form the final PCB.

There are provided a printed circuit board and a method of manufacturing the same. The printed circuit board include a glass plate, an insulating member penetrating through the glass plate, insulating layers disposed on a first surface and a second surface of the glass plate, and a via through the insulating member.

Through the use of a method of producing electronic components, a plurality of electronic components are obtained by cutting, along a predetermined cutting line, a laminate including a first circuit board and a second circuit board both mounted with circuit components. The method of producing electronic components includes: a stacking step of stacking the second circuit board on the first circuit board with a spacer interposed therewith, the first circuit board being provided with a filled via around a mounting region of the circuit components; a filling step of filling a filling space formed between the first circuit board and the second circuit board using the spacer with insulating resins; and a cutting step of cutting the laminate along the cutting line, the cutting line dividing the filled via, and exposing the filled via from a cut surface to acquire terminal portions of the electronic components.

A package comprises a body, and an electrically conductive pattern supported by said body. An interface portion is configured to receive a module to a removable attachment with the package. The electrically conductive pattern comprises, at least partly within said interface portion, a wireless coupling pattern that constitutes one half of a wireless coupling arrangement.

A flexible sheet of light-emitting diode (LED) light emitters includes a support substrate having a thermally conductive material. The flexible sheet of LED light emitters also has an LED emitter sheet overlying the support substrate, and the LED emitter sheet including a plurality of LED light emitters. The flexible sheet of LED light emitters also has a flexible circuit sheet overlying the LED emitter sheet, and a phosphor sheet overlying the flexible circuit sheet. The phosphor sheet includes a wave-length converting material. The flexible sheet of LED light emitters also has a lens sheet overlying the phosphor sheet. The lens sheet includes a plurality of lenses.

The invention provides a printed circuit board (10) including a first electrically conductive track (210), wherein the printed circuit board (10) comprises a set (15) of two printed circuit board areas (100) both comprising a part of the first electrically conductive track (210), wherein printed circuit board (10) further comprises a perforation line (300) between the two printed circuit board areas (100) for customizing the printed circuit board (10) into two physically separated printed circuit board area comprising parts (1100), wherein the perforation line (300) is configured as a non-straight line, wherein the perforation line (300) comprises relative to one of the printed circuit board areas (100), and in a plane of the printed circuit board (10), a first projecting part (311) and a first recessed part (312), wherein the first recessed part (312) is recessed relative to the first projecting part (311), wherein the first electrically conductive track (210) is intercepted by the perforation line (300) at the first recessed part (312).