A wiring board is provided with power supply patterns for each type of power supply of an IC. An IC has a plurality of power supply terminals for each type of power supply. For each type of power supply, two or more laminated capacitors are provided in parallel between the power supply of IC and a ground. Two or more laminated capacitors provided for each type of power supply include a laminated capacitor having a Q factor of less than about 0.5. For each type of power supply, in order to satisfy a target impedance, two or more laminated capacitors are arranged and distributed such that at least half of the plurality of power supply terminals are included in a region obtained by combining cover areas.

A high voltage power supply is disclosed. The high voltage power supply comprises a primary winding and one or more secondary windings. In one embodiment, a single secondary winding is used and the high voltage doubler circuit comprises a capacitor string and a diode string. In another embodiment, a plurality of secondary windings are used and the high voltage doubler circuit comprises a plurality of low voltage doubler circuits arranged in series. To create a more uniform distribution of voltage across the capacitors in the high voltage doubler circuit, one or more shields are disposed on the printed circuit board. In certain embodiments, a high voltage shield is disposed at the high voltage output and a low voltage shield is disposed at the low voltage end of the high voltage doubler circuit. One or more intermediate shields may be disposed in the high voltage doubler circuit.

A data transmission circuit board, a mobile industry processor interface and a device are provided. The data transmission circuit board includes: a wiring substrate; a plurality of data transmission line pairs on one side of the wiring substrate; and a plurality of transient voltage suppression diodes on the one side of the wiring substrate. Data transmission lines of the data transmission line pairs are coupled to the transient voltage suppression diodes in a one-to-one correspondence, the line width of at least one data transmission line is within a line width threshold range; and the transient voltage suppression diode is configured to discharge when a voltage to ground on the corresponding data transmission line is greater than a discharge voltage threshold, wherein the discharge voltage threshold is not less than a maximum voltage value of the differential signal transmitted on the data transmission line.

The present disclosure generally relates to a scalable computer circuit board having a first power level semiconductor package coupled to at least one base-level voltage regulator module, which is coupled to a plurality of connection receptacles that are configured for connecting with a voltage regulator module positioned on a second level, as a standardized base unit. To scale the base unit, a second power level semiconductor package may be exchanged for the first power level semiconductor package in conjunction with one or more voltage regulator module board being positioned over a corresponding number of base-level voltage regulator modules and coupled to their plurality of connection receptacles.

A semiconductor composite device is provided that includes a voltage regulator, a package board, and a load, and converts an input DC voltage into a different DC voltage to supply the converted DC voltage to the load. The VR includes a semiconductor active element. The package board includes a C layer in which a capacitor is formed, and an L layer in which an inductor is formed. A plurality of through holes penetrate the C layer and the L layer in a direction perpendicular to the mounting face in the package board. The capacitor is connected to the load through the through hole. The inductor is connected to the load through the through hole and to the VR through the through hole.

A board main body part has a multilayer structure with even-numbered layers including a first layer formed on a surface part on one side and a second layer formed on a surface part on the other side. On both of the first layer and the second layer, a low voltage region in which a low voltage circuit is disposed, a high voltage region in which high voltage circuits are disposed, and an insulating region in which the low voltage region is electrically isolated from the high voltage region are formed. At least a part of a first high voltage circuit is disposed in a first-layer high voltage region formed on the first layer, and at least a part of a second high voltage circuit is disposed in a second-layer high voltage region formed on the second layer.

Certain aspects of the present disclosure generally relate to a circuit board with ground vias offset from associated ground bumps. One example circuit board generally includes a first signal connection terminal configured to connect a signal line of the circuit board to an integrated circuit (IC); a ground plane having a first ground connection terminal disposed adjacent to the first signal connection terminal, the first ground connection terminal being configured to provide a ground connection between the ground plane and the IC; and a first ground via associated with and disposed adjacent to the first ground connection terminal and coupled to the ground plane, wherein, from an overhead view of the circuit board, the first ground via is located at a position that is offset from a first axis on which the first signal connection terminal and the first ground connection terminal are disposed.

A data transmission circuit board, a mobile industry processor interface and a device are provided. The data transmission circuit board includes: a wiring substrate; a plurality of data transmission line pairs on one side of the wiring substrate; and a plurality of transient voltage suppression diodes on the one side of the wiring substrate. Data transmission lines of the data transmission line pairs are coupled to the transient voltage suppression diodes in a one-to-one correspondence, the line width of at least one data transmission line is within a line width threshold range; and the transient voltage suppression diode is configured to discharge when a voltage to ground on the corresponding data transmission line is greater than a discharge voltage threshold, wherein the discharge voltage threshold is not less than a maximum voltage value of the differential signal transmitted on the data transmission line.

The present disclosure generally relates to a scalable computer circuit board having a first power level semiconductor package coupled to at least one base-level voltage regulator module, which is coupled to a plurality of connection receptacles that are configured for connecting with a voltage regulator module positioned on a second level, as a standardized base unit. To scale the base unit, a second power level semiconductor package may be exchanged for the first power level semiconductor package in conjunction with one or more voltage regulator module board being positioned over a corresponding number of base-level voltage regulator modules and coupled to their plurality of connection receptacles.

An electronic module, such as a VRM, has a power inductor and power wave pins disposed on a bottom surface of a circuit board so as to reduce the size and increase the heat dissipation capability of the VRM.