The present disclosure provides a method far preparing a semiconductor package. The semiconductor package includes a semiconductor device having an upper surface and a side, wherein the upper surface and the side form a corner of the semiconductor device. The semiconductor package also includes a lateral bump structure disposed on the side and implementing a lateral signal path of the semiconductor device. The semiconductor package further includes a vertical hump structure disposed over the upper surface and implementing a vertical signal path of the semiconductor device.

A semiconductor device includes a semiconductor substrate; at least one transistor located on the semiconductor substrate and including a plurality of semiconductor layers; an electrode provided for the transistor; an organic insulating film having an opening in a region overlapping the transistor and the electrode in plan view in a first direction perpendicular to the semiconductor substrate; and a bump located over the at least one transistor in plan view in the first direction and electrically connected to the electrode through the opening of the organic insulating film. The width of the bump in a second direction parallel to the semiconductor substrate is smaller than the width of the opening of the organic insulating film in the second direction.

A semiconductor package includes a first device and a bump structure disposed over the first device. In some embodiments, the first device has a first upper surface and a first side, wherein the first upper surface and the first side form a first corner of the first device. In some embodiments, the bump structure is disposed over the first upper surface and extends laterally across the first side of the first device. The lateral extension of the bump structure across the first side of the semiconductor device can contact a corresponding conductor of a laterally adjacent device to implement a lateral signal path between the semiconductor device and the laterally adjacent device in the absence of a redistribution structure corresponding to the redistribution layer.

One aspect of the invention relates to a method for producing a chip assemblage. Two or more chip assemblies are produced in each case by cohesively and electrically conductively connecting an electrically conductive first compensation lamina to a first main electrode of a semiconductor chip. A control electrode interconnection structure is arranged in a free space between the chip assemblies. Electrically conductive connections are produced between the control electrode interconnection structure and control electrodes of the semiconductor chips of the individual chip assemblies. The chip assemblies are cohesively connected by means of a dielectric embedding compound.

A high-frequency circuit includes: a first substrate; a transmission line formed on the first substrate and having first and second output portions branched from an input portion; a second substrate; first and second pads formed on the second substrate; a first wire connecting the first output portion to the first pad; and a second wire connecting the second output portion to the second pad, wherein an electrical length from the input portion to an edge of the second output portion is longer than an electrical length from the input portion to an edge of the first output portion, and a length from a junction between the second wire and the second output portion to the edge of the second output portion is longer than a length from a junction between the first wire and the first output portion to the edge of the first output portion.

The present technology relates to a semiconductor package. The semiconductor package comprises: a first component comprising a plurality of first dies stacked on top of each other, each of first dies comprising at least one side surface and an electrical contact exposed on the side surface, and the plurality of first dies aligned so that the corresponding side surfaces of all first dies substantially coplanar with respect to each other to form a common sidewall; a first conductive pattern formed over the sidewall and at least partially spaced away from the sidewall, the first conductive pattern electrically interconnecting the electrical contacts of the plurality of first dies; at least one second component; and a second conductive pattern formed on a surface of the second component, the second conductive pattern affixed and electrically connected to the first conductive pattern formed over the sidewall of the first component.

A semiconductor package includes a semiconductor device having an upper surface and a side, wherein the upper surface and the side form a corner of the semiconductor device. The semiconductor package also includes a lateral bump structure disposed on the side and implementing a lateral signal path of the semiconductor device. The semiconductor package further includes a vertical bump structure disposed over the upper surface and implementing a vertical signal path of the semiconductor device.

In a conventional electronic device and a method of manufacturing the same, reduction in cost of the electronic device is hindered because resin used in an interconnect layer on the solder ball side is limited. The electronic device includes an interconnect layer (a first interconnect layer) and an interconnect layer (a second interconnect layer). The second interconnect layer is formed on the undersurface of the first interconnect layer. The second interconnect layer is larger in area seen from the top than the first interconnect layer and is extended to the outside from the first interconnect layer.

A semiconductor package includes: a first substrate including lower bonding pads; at least one semiconductor chip disposed on the first substrate; bumps disposed on a first surface of the first substrate; and a mold layer disposed on the first substrate and covering the at least one semiconductor chip, wherein the bumps include: a pillar portion bonded to the first surface of the first substrate; a solder portion bonded to a first surface of the pillar portion; and a metal layer including a material including high-melting-point metal atoms, wherein the metal layer covers a first surface of the solder portion, wherein the solder portion includes the high-melting-point metal atoms.

Aspects disclosed in the detailed description include an integrated circuit (IC) package employing a metal block with metal interconnects thermally coupling a semiconductor die (die) to an interposer substrate for dissipating thermal energy in the die. The die is coupled to a package substrate to provide signal routing paths to the die. To facilitate additional dies being stacked in the IC package as a three-dimensional (3D) IC (3DIC) package, the IC package also includes an interposer substrate adjacent to the die. The interposer substrate supports providing additional signal routing paths to the package substrate. The interposer substrate also includes a metal block which comprises a plurality of metal layers and is thermally coupled to the die and a metal interconnect(s) in the interposer substrate to dissipate thermal energy from the die through the metal block and through the coupled metal interconnect(s).