An electronic component module includes a first module including a sealing portion disposed on a first surface of a first board and a shielding layer disposed on a surface of the sealing portion, a second module spaced apart from the first module, a connection board having greater flexibility than the first board and connecting the first module to the second module, and a first ground line electrically connected to a ground layer of the first board and disposed on a surface of the connection board, and at least a portion of the shielding layer is electrically connected to the ground layer of the first board.

A component package includes a printed circuit board; a first electronic component disposed in a first region on the printed circuit board; a second electronic component disposed in a second region on the printed circuit board; and a metal wall disposed on the printed circuit board and spatially partitioning the first region and the second region on a plane. The metal wall is directly connected to the printed circuit board.

Feed forward compensation of parasitic capacitance in a device frontend is provided. A feed forward element is positioned along at least a portion of a length of a first input resistance and a distance away from the first input resistance. In some implementations, the feed forward element has a width that is increasing along the at least a portion of the length of the first input resistance. The feed forward element is operative to introduce an element capacitance that offsets a parasitic capacitance in a volume surrounding the first input resistance.

An electronic component includes: an insulating substrate including a first main surface and a second main surface opposite to each other in a thickness direction and a side surface with a plurality of ground electrodes exposed thereto; conductive films each covering a surface of a corresponding one of the plurality of ground electrodes exposed to the side surface of the insulating substrate; and a shielding film covering the first main surface and the side surface of the insulating substrate and surfaces of the conductive films. The plurality of ground electrodes includes a first ground electrode and a second ground electrode, the first ground electrode and the second ground electrode being exposed to the side surface of the insulating substrate at a position closest to the first main surface and at a position closest to the second main surface, respectively.

The present invention discloses a method for manufacturing a multi-layer flexible circuit board, comprising the steps of: (1) manufacturing a double-sided FPC flexible board; (2) manufacturing a novel material layer structure; (3) hot pressing at least one group of upeer novel material layer structures on the circuits on the upper and/or lower surfaces of the double-sided FPC flexible board; forming a protective layer on the circuits of an outermost novel material layer structure and/or on exposed circuits of the double-sided FPC flexible board so as to obtain a multi-layer flexible circuit board. The present invention also discloses a multi-layer flexible circuit board manufactured by performing the above-mentioned method. The manufacturing process of the present invention is simplified, convenient and efficient; the multi-layer flexible circuit board not only greatly simplifies the novel material layer structure and reduces the overall thickness, but also has the function of high-speed transmission of high-frequency signals, especially suitable for new 5G technology products. It can protect and resist the migration of copper ions when it is energized between circuits so as to ensure the safety and normal operation of circuits.

In one example, an apparatus comprises: a first metal layer including a first segment and a second segment, in which the first segment is electrically coupled to a single-ended signal terminal, the second segment has a disconnected end; a second metal layer including a third segment and a fourth segment, in which the third segment is magnetically coupled to the first segment, the fourth segment is magnetically coupled to the second segment, a first end of the third segment and a first end of the fourth segment are electrically coupled at a center tap, and a second end of the third segment and a second end of the fourth segment are electrically coupled to respective first and second signal terminals of a pair of differential signal terminals; and a phase adjustment device proximate the center tap and electrically coupled to a second voltage reference terminal.

A transmission line includes a substrate including insulator layers, a mounting electrode on a front layer of the substrate, a signal conductor, a first ground conductor, a first connecting electrode that electrically connects the mounting electrode and the signal conductor and is between the signal conductor and the first ground conductor in a laminating direction, a first inter-layer connecting conductor that is electrically connected between the mounting electrode and the first connecting electrode and is bonded to the first connecting electrode, and a second inter-layer connecting conductor that is electrically connected between the signal conductor and the first connecting electrode, is bonded to the first connecting electrode, and does not overlap with the first inter-layer connecting conductor when viewed in the laminating direction. The first ground conductor does not overlap with at least a portion of the first connecting electrode when viewed in the laminating direction.

An electronic device having at least one circuit board. The circuit board has a predetermined pattern of solder bumps facilitating a ground connection with a first enclosure member and/or a second enclosure member. The at least one circuit board is sandwiched between the first and second enclosure members, each of the first and second enclosure members has a surface facing the circuit board and the surface facing the circuit board has a bead extending therefrom contacting the predetermined pattern of solder bumps to complete the ground connection.

A system for driving power devices is provided, and the system includes a heat dissipation plate, semiconductor modules, gate plates, a control board, a bridge module, and a terminal module. The semiconductor modules are disposed on the heat dissipation plate. Each gate plate is disposed on the corresponding semiconductor module and includes first driving terminal. The control board is disposed on the heat dissipation plate. The bridge module and the terminal module are electrically connected to each other, disposed on the control board, and arranged sequentially in a direction from a center to an edge of the control board. The bridge module includes a plurality of driving bridge plates, and each driving bridge plate is electrically coupled to the control board. The terminal module includes a plurality of second driving terminals, and each second driving terminal is electrically connected to the corresponding driving bridge plate and first driving terminal.

An electronic device including a substrate on which an electronic component is mounted according to various embodiments may include: a first electromagnetic interference (EMI) shield configured to shield the electronic component included in a first region of the substrate; and a second EMI shield supported by at least a part of the first EMI shield and configured to shield the electronic component included in a second region of the substrate.