A stretchable circuit board includes a stretchable base material; a stretchable conductive pattern formed on at least one main surface of the stretchable base material and having stretchability; and a reinforcing base having higher rigidity than the stretchable base material, wherein the reinforcing base reinforces the stretchable base material by being directly or indirectly laminated on the stretchable base material so as to surround at least a part of a formation region of the stretchable conductive pattern in the stretchable base material in a plan view.

Provided is a conductive pattern having at least one unit conductive pattern forming one touch pixel according to an aspect of the present invention. The at least one unit conductive pattern includes a plurality of nanostructures each having opposite ends. A ratio of nanostructures, both opposite ends of which are in contact with edges of the at least one unit conductive pattern to all nanostructures included in the at least one unit conductive pattern is 70% or more.

A semiconductor die is mounted at a die area of a ball grid array package that includes an array of electrically-conductive ball. A power channel conveys a power supply current to the semiconductor die. The power channel is formed by an electrically-conductive connection plane layers extending in a longitudinal direction between a distal end at a periphery of the package and a proximal end at the die area. A distribution of said electrically-conductive balls is made along the longitudinal direction. The electrically-conductive connection plane layer includes subsequent portions in the longitudinal direction between adjacent electrically-conductive balls of the distribution. Respective electrical resistance values of the subsequent portions monotonously decrease from the distal end to the proximal end. A uniform distribution of power supply current over the length of the power channel is thus facilitated.

A battery pack includes battery cells arranged in a first direction, and a busbar assembly coupled to upper portions of the battery cells, the busbar assembly having a busbar electrically connected to the battery cells, a flexible substrate configured to measure a state information of the battery cells, and an insulating film surrounding the busbar and the flexible substrate.

Provided is a current sensing device including: a laminate having a plurality of insulating layers laminated therein; a current sensing element provided in an inner layer of the laminate; a current wire configured to flow current to the current sensing element, the current wire being provided with respect to the current sensing element via an interlayer insulating layer; a plurality of current vias configured to connect the current sensing element and the current wire so as to penetrate through the interlayer insulating layer; and a voltage sensing via configured to obtain a voltage drop in the current sensing element, the voltage sensing via being electrically connected to the current sensing element.

The disclosure relates to a printed circuit board arrangement with a printed circuit board with at least two current conducting layers. The current conducting layers extend in an axial direction of the printed circuit board and are arranged in succession in a thickness direction of the printed circuit board. The printed circuit board arrangement has a busbar which is arranged on a lateral surface of the printed circuit board and is in contact with at least one part of the current conducting layers of the printed circuit board.

Provided is a power conversion circuit for achieving a power conversion device capable of suppressing charging/discharging of a parasitic capacitor caused by high-frequency switching, and of reducing a loss of a semiconductor switching element. The power conversion circuit includes: a circuit board including a plurality of layers including two or more layers, on which circuit patterns are formed; and a plurality of semiconductor switching elements connected to the circuit patterns of the circuit board, and configured to perform switching for power conversion. In the circuit board, a plurality of control ground patterns for different nodes, which are configured to drive the plurality of semiconductor switching elements, are arranged so as not to overlap one another in plan view.

The present disclosure provides a battery module comprising a circuit board, the circuit board comprises a conductive layer, a first pad and a second pad. The conductive layer is formed with a sampling circuit, the sampling circuit comprises: a sampling end portion; an outputting end portion; a first branch path formed with a first fusing zone; and a second branch path formed with a second fusing zone. The first pad is provided on the sampling end portion, the second pad is provided on the second branch path. When the first fusing zone is fused, the circuit board can be quickly repaired by means of the second branch path and the second pad to electrically connect the sampling end portion and the outputting end portion, thereby achieving the purpose of reusing the circuit board, therefore the entire battery module is not scrapped and the utilization of the battery module is improved.

Provided is a circuit module including a power supply chip module, a load chip module, and a system board. A power supply output terminal group of the power supply chip module is arranged side by side in a row along a side of the power supply chip module board, the power supply input terminal group of a load chip module includes a specific terminal group arranged in a specific row that is a row along a side of the load chip module board, and a wiring width along an arrangement direction of the power supply output terminal group of a wiring pattern in which the power supply output terminal group is connected to the system board is equal to or more than a wiring width W31 along an arrangement direction of the specific terminal group of the wiring pattern in which the specific terminal group is connected to the system board.

An object of the present invention is to decrease the resistance of a power supply line, to suppress a voltage drop in the power supply line, and to prevent defective display. A connection terminal portion includes a plurality of connection terminals. The plurality of connection terminals is provided with a plurality of connection pads which is part of the connection terminal. The plurality of connection pads includes a first connection pad and a second connection pad having a line width different from that of the first connection pad. Pitches between the plurality of connection pads are equal to each other.