A printed circuit board includes a first transmission line provided on an insulating base, a first ground conductor, a notch portion that exposes a part of the first ground conductor, a conductor provided in the notch portion and electrically connected to the first ground conductor, and a first electrode exposed on a main surface of the insulating base facing a flexible board and electrically connected to the first transmission line. The flexible board includes a second transmission line provided on an insulating sheet, a second ground conductor, a second electrode exposed on a main surface of the insulating sheet facing the printed circuit board and connected to the second transmission line, and a third electrode exposed on the main surface of the insulating sheet and connected to the second ground conductor. The conductor and the third electrode are connected by solder.

Research on practical realization of various types of printable devices has progressed, and the realization of devices in which these printable devices are integrated on a flexible board is expected. However, there is the problem that, if a plurality of printable devices are simply integrated on the same board, the area of the integrated device increases, and the yield ratio greatly decreases. An integration technique that solves the problem of an increase in the area and a decrease in the yield ratio is in demand. Electronic devices to be integrated are formed on individual boards, the boards are laid to overlap each other in a predetermined relationship, and then through-vias are formed at predetermined positions. With this, the electronic devices are electrically connected to each other, and function as an integrated device.

A flexible printed circuit and printed circuit board soldered structure is provided. The structure includes signal transmission lines which dispense with any through hole, thereby enhancing integrity of high-frequency signals. The special design of the signal line structure of the flexible printed circuit and the printed circuit board together provides a satisfactory high-frequency signal transmission interface and enables a soldering technique which is highly practicable and compatible with the flexible printed circuit and printed circuit board soldered structure.

The printed board includes a slit portion and a first conductive member that is provided straddling the slit portion. In a state in which the printed board is attached to an apparatus to which one end of a second conductive member having an elastic force is connected, another end of the second conductive member contacts the first conductive member, and the another end of the second conductive member passes through the slit portion.

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.

Disclosed is a motherboard comprising at least one printed circuit board (PCB), referred to as the motherboard PCB, at least one planar transformer, which is mounted on the motherboard PCB, and a plurality of electronic components, which are also mounted on the motherboard PCB. The planar transformer comprises at least one printed circuit board with windings and a connection interface, a magnetic core arranged on the printed circuit board so as to interact with the windings, and at least one electronic component mounted on the printed circuit board.

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 light-emitting diode (LED) tube lamp with overcurrent and/or overvoltage protection capabilities includes a lamp tube, a first rectifying circuit, a filtering circuit, an LED lighting module, and a protection circuit. The lamp tube has pins for receiving an external driving signal. The first rectifying circuit is for rectifying the external driving signal to produce a rectified signal. The filtering circuit is for filtering the rectified signal to produce a filtered signal. The LED lighting module includes an LED module, wherein the LED lighting module is configured to receive the filtered signal to produce a driving signal, and the LED module is for receiving the driving signal for emitting light. The protection circuit is configured to determine whether to enter a protection state, wherein upon entering the protection state, the protection circuit works to limit or restrain the level of the filtered signal.

A wiring substrate comprises an insulating substrate and an external electrode on the insulating substrate. The insulating substrate comprises a lateral surface comprising a cutout. The cutout extends to a lower surface of the insulating substrate. The external electrode extends from an inner surface of the cutout to the lower surface of the insulating substrate. The insulating substrate comprises a protrusion at a lower end portion of the inner surface of the cutout. The protrusion protrudes from the inner surface of the cutout toward the lateral surface of the insulating substrate.

A fluid control apparatus is provided which makes it possible to effortlessly perform cable connection even when a plurality of the fluid control apparatuses are disposed adjacent to each other. The fluid control apparatus includes fluid control units to control a flow rate or pressure of a fluid, an electric circuit board to send and receive a signal to and from the fluid control units, a casing to accommodate therein the fluid control units and the electric circuit board, and an apparatus-side connector interposed between the electric circuit board and a cable electrically connected thereto. The fluid control apparatus further includes a connector board configured to mount thereon the apparatus-side connector. The connector board is secured to the electric circuit board with at least a part of the connector board in surface contact with the electric circuit board, or overlapping the electric circuit board with a clearance therebetween.