A non-conductive magnetic shield material is provided for use in magnetic shields of semiconductor packaging. The material is made magnetic by the incorporation of ferromagnetic particles into a polymer matrix, and is made non-conductive by the provision of an insulating coating on the ferromagnetic particles.

A non-conductive magnetic shield material is provided for use in magnetic shields of semiconductor packaging. The material is made magnetic by the incorporation of ferromagnetic particles into a polymer matrix, and is made non-conductive by the provision of an insulating coating on the ferromagnetic particles.

In some embodiments, the present application provides a memory device. The memory device includes a chip that includes a magnetic random access memory (MRAM) cell. A magnetic-field-shielding structure comprised of conductive or magnetic material at least partially surrounds the chip. The magnetic-field-shielding structure comprises a sidewall region that laterally surrounds the chip, an upper region extending upward from the sidewall region, and a lower region extending downward from the sidewall region. At least one of the upper region and/or lower region terminate at an opening over the chip.

A current sensor package, comprises a current path and a sensing device. The sensing device is spaced from the current path, and the sensing device is configured for sensing a magnetic field generated by a current flowing through the current path. Further, the sensing device comprises a sensor element. The sensing device is electrically connected to a conductive trace. An encapsulant extends continuously between the current path and the sensing device.

A current sensor package, comprises a current path and a sensing device. The sensing device is spaced from the current path, and the sensing device is configured for sensing a magnetic field generated by a current flowing through the current path. Further, the sensing device comprises a sensor element. The sensing device is electrically connected to a conductive trace. An encapsulant extends continuously between the current path and the sensing device.

An electronic package, a semiconductor package structure and a method for manufacturing the same are provided. The electronic package includes a carrier, a first electronic component, an electrical extension structure, and an encapsulant. The carrier has a first face and a second face opposite to the first face. The first electronic component is adjacent to the first face of the carrier. The electrical extension structure is adjacent to the first face of the carrier and defines a space with the carrier for accommodating the first electronic component, the electrical extension structure is configured to connect the carrier with an external electronic component. The encapsulant encapsulates the first electronic component and at least a portion of the electrical extension structure.

A multi-chip module includes two silicon bridge interconnects and three components that are tied together by the bridges with one of the components in the center. At least one of the silicon bridge interconnects is bent to create a non-planar chip-module form factor. Cross-connected multi-chip silicon bent-bridge interconnect modules include the two silicon bridges contacting the center component at right angles to each other, plus a fourth component and a third silicon bridge interconnect contacting the fourth component and any one of the original three components.

A semiconductor device is provided to reduce thermal fatigue in a junction portion of an external wiring to enhance long-term reliability, where the semiconductor device includes a semiconductor substrate, a transistor portion and a diode portion that are alternately arranged along a first direction parallel to a front surface of the semiconductor substrate inside the semiconductor substrate, a surface electrode that is provided above the transistor portion and the diode portion and that is electrically connected to the transistor portion and the diode portion, an external wiring that is joined to the surface electrode and that has a contact width with the surface electrode in the first direction, the contact width being larger than at least one of a width of the transistor portion in the first direction and a width of the diode portion in the first direction.

Power semiconductor module, including a base plate with at least one substrate located on the base plate, wherein an electronic circuit is provided on the at least one substrate, wherein located on the at least one substrate are electrical connectors comprising a DC+ power terminal, a DC power terminal and an AC power terminal and further a control connector, wherein the power semiconductor module is designed as a half-bridge module including a first amount of switching power semiconductor devices and a second amount of switching power semiconductor devices, wherein the base plate includes a contact area, a first device area and a second device area, wherein the contact area is positioned in a center of the base plate such, that the first device area is positioned at a first side of the contact area and that the second device area is positioned at a second side of the contact area, the second side being arranged opposite to the first side, wherein the DC+ power terminal, the DC power terminal, the AC power terminal and the control connector are positioned in the contact area, wherein the first amount of switching power semiconductor devices is positioned in the first device area and wherein the second amount of switching power semiconductor devices is positioned in the second device area, wherein all the power semiconductor devices in the first device area are located in two parallel lines being aligned parallel to the width of the base plate and wherein all the power semiconductor devices in the second device area are located in two parallel lines being aligned parallel to the width of the base plate.

A non-conductive magnetic shield material is provided for use in magnetic shields of semiconductor packaging. The material is made magnetic by the incorporation of ferromagnetic particles into a polymer matrix, and is made non-conductive by the provision of an insulating coating on the ferromagnetic particles.