An electronic module has a first substrate 11, a first electronic element 13, a second electronic element 23, a second substrate 21, a first terminal part 110 provided on a side of the first substrate 11 and a second terminal part 120 provided on a side of the second substrate 21. The first terminal part 110 has a first surface direction extending part 114 and a first normal direction extending part 113 extending toward one side or the other side. The second terminal part 120 has a second surface direction extending part 124 and a second normal direction extending part 123 extending toward one side or the other side. The second surface direction extending part 124 is provided on one side of the first surface direction extending part 114, and the first surface direction extending part 114 and the second surface direction extending part 124 overlap one another in a surface direction.

A semiconductor composite device includes active elements and passive elements constituting a voltage regulator and disposed in association with a plurality of channels, a load to be supplied with a direct-current voltage regulated by the voltage regulator, and a wiring board electrically connected to the active elements, the passive elements, and the load. A plurality of capacitors disposed in the channels include an integrally formed capacitor array including a plurality of capacitor portions disposed in a plane. The capacitor array includes a plurality of through hole conductors extending through the capacitor array in a direction perpendicular to a mounting surface of the wiring board. At least a part of the capacitor array is positioned to overlap the load when viewed from the mounting surface of the wiring board.

A multi-component transistor structure includes components each comprising an individual, discrete, and separate component substrate and a component transistor. The component transistor includes a transistor element having a transistor element resistance. A component connection is disposed external to the transistor element and has a connection resistance. The component connection electrically connects the transistor elements in the components in parallel. The connection resistance is less than the transistor element resistance of at least one corresponding transistor element, less than an average of the transistor element resistances of all of the corresponding transistor elements, or less than the sum of all of the transistor element resistances of all of the corresponding transistor elements. The component transistors are functionally similar and at least one of the components is disposed on another different one of the components in a component stack.

A semiconductor device structure and a method for making a semiconductor device. As non-limiting examples, various aspects of this disclosure provide various semiconductor package structures, and methods for making thereof, that comprise a thin fine-pitch redistribution structure.

A package includes a corner, a device die, a molding material molding the device die therein, and a plurality of bonding features. The plurality of bonding features includes a corner bonding feature at the corner, wherein the corner bonding feature is elongated. The plurality of bonding features further includes an additional bonding feature, which is non-elongated.

A relay substrate in which a circuit pattern and an external electrode are integrated on a insulating plate is used in the semiconductor device. Such configuration makes it possible to reduce a resistance in a current path while preventing the problems occurring when the external electrode is soldered on the semiconductor chip.

A device is disclosed which includes at least one integrated circuit die, at least a portion of which is positioned in a body of encapsulant material, and at least one conductive via extending through the body of encapsulant material.

A semiconductor device includes an interposer disposed on a substrate. A first major surface of the interposer faces the substrate. A system on a chip is disposed on a second major surface of the interposer. The second major surface of the interposer opposes the first major surface of the interposer. A plurality of first passive devices is disposed in the first major surface of the interposer. A plurality of second passive devices is disposed on the second major surface of the interposer. The second passive devices are different devices than the first passive devices.

A power module includes a multilayer circuit board, and first and second three-phase inverters, which are mounted on the multilayer circuit board to be stacked each other. A positive-electrode-side power source conductive trace of the first three-phase inverter and a negative-electrode-side power source conductive trace of the second three-phase inverter are disposed to at least partially face each other in a stacking direction of the multilayer circuit board, such that currents respectively flow through the power source conductive traces in opposite directions in a facing section. A negative-electrode-side power source conductive trace of the first three-phase inverter and a positive-electrode-side power source conductive trace of the second three-phase inverter are disposed to at least partially face each other in the stacking direction of the multilayer circuit board), such that currents respectively flow through the power source conductive traces in opposite directions in a facing section.

An electronic power device including: a first electronic power component in which all the electrodes are arranged at a first main face of the first electronic power component; and an electric contact element in which a first main face is arranged against the first main face of the first electronic power component and which includes plural separate electrically conductive portions to which the electrodes of the first electronic power component are electrically connected. The first electronic power component and the electric contact element together form a stack such that a first lateral face of each of the portions of the electric contact element, substantially perpendicular to the first main face of the electric contact element, is arranged against at least one metallization of a support forming an electric contact of the first electronic power component.