A first capacitance C.sub.1 exists between a first connection conductor (21) as well as a first component (31) and a ground layer (3), and a second capacitance C.sub.2 exists between a second connection conductor (22) as well as a second component (32) and the ground layer (3). The length of the first conductor (11) and the length of the second conductor (12) are each adjusted depending on a difference ΔC between the first capacitance C.sub.1 and the second capacitance C.sub.2.

An electronic device is disclosed. An electronic device according to an embodiment may include: a first Printed Circuit Board (PCB), a second PCB, a Radio Frequency (RF) transceiver disposed on the first PCB, a Flexible Printed Circuit Board (FPCB) coupled with the first PCB and the second PCB and electrically coupled with the RF transceiver, the FPCB including a transmission line of a wireless communication signal, an amplifier disposed on the second PCB and electrically coupled with the RF transceiver by the FPCB, a first antenna electrically coupled with the amplifier through the second PCB and configured to receive a wireless communication signal corresponding to a first frequency, and a second antenna electrically coupled with the amplifier through the second PCB and configured to receive a wireless communication signal corresponding to a second frequency. The first antenna and the second antenna may be disposed closer to the second PCB than the first PCB in the electronic device. The amplifier may amplify a wireless communication signal received from the first antenna and second antenna.

Disclosed is a printed circuit board including an overvoltage controlling element and an electronic device including the same. The printed circuit board includes a first outer layer, a second outer layer, at least one inner layer stacked between the first and second outer layers, an overvoltage controlling element comprising overvoltage controlling circuitry mounted on the first outer layer and including a plurality of terminals of which a first terminal is connected to a ground, and a conductive area configured to transfer at least a part of a first voltage applied from an external power source to an external IC and to transfer a remaining part of the first voltage to the overvoltage controlling element.

Provided are a radio frequency identification tag and a method of manufacturing the same. The radio frequency identification tag includes a substrate, an antenna unit provided on the substrate and configured to transmit and receive signals, an integrated circuit unit spaced apart from the antenna unit on the substrate, and an interrupter and a delay circuit unit connected in parallel between the antenna unit and the integrated circuit unit, wherein the interrupter includes a variable portion and a fixed portion opposite the variable portion, wherein the delay circuit unit includes a capacitor and a resistor.

A functional contactor is provided. The functional contactor contains a conductive elastic portion having elasticity and electrically contacting one of a circuit board of an electronic device, a bracket coupled to the circuit board, and a conductor which can come into contact with the human body; a substrate containing a plurality of dielectric layers; and a functional element embedded in the substrate so as to be electrically connected in series to the conductive elastic portion.

Obtained is a power conversion device including a small-sized and low-cost fuse portion which allows overcurrent to be assuredly interrupted when being applied and allows a semiconductor element to be protected from a short-circuit fault or the like. The power conversion device includes: a circuit board; a semiconductor element mounted on the circuit board; a snubber capacitor; a snubber circuit wire which connects the snubber capacitor in parallel to the semiconductor element; and a fuse portion formed at a part of the snubber circuit wire.

A combination structure of a clamping member and a circuit board for a signal connector is disclosed. The clamping member includes two clamping members fixedly connected to two sides of the circuit board. Each clamping member has a pair of first positioning pins and a pair of second positioning pins. Thereby, the center of the guide pin can be guided and the guide pin won't be loosened, so as to improve the stability of the signal and reduce the loss.

An article for a power inverter, includes a multilayer printed circuit board having a first and second electrically conductive wiring layer and at least a first dielectric layer interposed between the first and second electrically conductive wiring layers. Each conductive wiring layer includes a common input and output line, the common input and output lines at least partially overlapping one another in a projection along a thickness of the multilayer printed circuit board. A set of input mounting pads is carried by the first common input line and a set of input mounting pads is carried by the second common input line, the input mounting pads of the second set of input mounting pads are interleaved with the input mounting pads of the first set of input mounting pads along a first axis. The article further includes a set output mounting pads carried by the common output line.

Provided is a flexible printed circuit including: a film-shaped insulating base material having flexibility and having a withstand voltage value of at least 2000 V; and an electric conductor layer formed on the insulating base material and forming a circuit pattern, wherein with respect to the insulating base material, a principal component thereof is a polyimide and a filler content thereof is 0%. Thus, a flexible printed circuit can be obtained that has an insulating base material which suppresses decrease in withstand voltage performance even in a high humidity environment.

Provided is a physiological information detection sensor capable of implementing miniaturization by substantially securing a creepage distance and an air distance (e.g., implementing defibrillation protection). The physiological information detection sensor includes: a plurality of first substrates arranged in multiple tiers; a second substrate; a first connecting portion that electrically connects adjacent first substrates to each other among the plurality of first substrates; and an insulating member. Each of the plurality of first substrates has a defibrillation protection resistor mounted thereon and electrically connected to a physiological information detection unit. The second substrate has a circuit mounted thereon to process physiological information input from the physiological information detection unit via the defibrillation protection resistor. The insulating member is disposed between adjacent first substrates among the plurality of first substrates.