The present disclosure is directed to systems and methods for improving the impedance matching of semiconductor package substrates by incorporating one or more magnetic build-up layers proximate relatively large diameter, relatively high capacitance, conductive pads formed on the lower surface of the semiconductor package substrate. The one or more magnetic layers may be formed using a magnetic build-up material deposited on the lower surface of the semiconductor package substrate. Vias conductively coupling the conductive pads to bump pads on the upper surface of the semiconductor package substrate pass through and are at least partially surrounded by the magnetic build-up material.

The present disclosure is directed to systems and methods for improving the impedance matching of semiconductor package substrates by incorporating one or more magnetic build-up layers proximate relatively large diameter, relatively high capacitance, conductive pads formed on the lower surface of the semiconductor package substrate. The one or more magnetic layers may be formed using a magnetic build-up material deposited on the lower surface of the semiconductor package substrate. Vias conductively coupling the conductive pads to bump pads on the upper surface of the semiconductor package substrate pass through and are at least partially surrounded by the magnetic build-up material.

The present disclosure is directed to systems and methods for improving the impedance matching of semiconductor package substrates by incorporating one or more magnetic build-up layers proximate relatively large diameter, relatively high capacitance, conductive pads formed on the lower surface of the semiconductor package substrate. The one or more magnetic layers may be formed using a magnetic build-up material deposited on the lower surface of the semiconductor package substrate. Vias conductively coupling the conductive pads to bump pads on the upper surface of the semiconductor package substrate pass through and are at least partially surrounded by the magnetic build-up material.

The present disclosure is directed to systems and methods for improving the impedance matching of semiconductor package substrates by incorporating one or more magnetic build-up layers proximate relatively large diameter, relatively high capacitance, conductive pads formed on the lower surface of the semiconductor package substrate. The one or more magnetic layers may be formed using a magnetic build-up material deposited on the lower surface of the semiconductor package substrate. Vias conductively coupling the conductive pads to bump pads on the upper surface of the semiconductor package substrate pass through and are at least partially surrounded by the magnetic build-up material.

The present disclosure is directed to systems and methods for improving the impedance matching of semiconductor package substrates by incorporating one or more magnetic build-up layers proximate relatively large diameter, relatively high capacitance, conductive pads formed on the lower surface of the semiconductor package substrate. The one or more magnetic layers may be formed using a magnetic build-up material deposited on the lower surface of the semiconductor package substrate. Vias conductively coupling the conductive pads to bump pads on the upper surface of the semiconductor package substrate pass through and are at least partially surrounded by the magnetic build-up material.

An electrical module and a method of producing such an electrical module are disclosed. The electrical module includes: a ceramic circuit carrier, an electrical component arranged on the ceramic circuit carrier, and a substrate having a potting material, wherein the ceramic circuit carrier and the electrical component are arranged in the substrate. The electrical module has an upper side that forms electrical contact areas. and stepped metal structures arranged on the upper side of the electrical module. Each metal structure has regions of different thickness. The metal structures form on their upper side in each case one of the electrical contact areas of the electrical module and contact on their underside in a region of increased thickness in each case one of the electrical contacts on the upper side of the electrical component.

The present disclosure is directed to systems and methods for improving the impedance matching of semiconductor package substrates by incorporating one or more magnetic build-up layers proximate relatively large diameter, relatively high capacitance, conductive pads formed on the lower surface of the semiconductor package substrate. The one or more magnetic layers may be formed using a magnetic build-up material deposited on the lower surface of the semiconductor package substrate. Vias conductively coupling the conductive pads to bump pads on the upper surface of the semiconductor package substrate pass through and are at least partially surrounded by the magnetic build-up material.

A method for die pair partitioning can include providing a first circuit die having a first metal stack. The method can additionally include positioning a second circuit die having a second metal stack in a manner that places a temperature sensor in a transistor layer of the second circuit die in planar proximity to at least one hot spot located in an additional transistor layer of the first circuit die. The method can also include connecting the first metal stack of the first circuit die to the second metal stack of the second circuit die. Various other methods, systems, and computer-readable media are also disclosed.

A method for providing backside power can include providing a first circuit die having a first metal stack. The method can also include connecting a second metal stack of a second circuit die to the first metal stack of the first circuit die, wherein a backside power delivery network is located in a passivation layer of at least one of the first circuit die or the second circuit die. Various other methods, systems, and computer-readable media are also disclosed.

A method for implementing shared metal connectivity between 3D stacked circuit dies can include providing a first circuit die having a first metal stack. The method can additionally include providing a second circuit die having a second metal stack, wherein at least one metal layer of the second metal stack is utilized by both the first circuit die and the second circuit die. The method can also include connecting the second metal stack to the first metal stack of the first circuit die. Various other methods, systems, and computer-readable media are also disclosed.