A lead frame includes a first outer lead portion and a second outer lead portion which is arranged to oppose to the first outer lead portion with an element-mounting region between them. An inner lead portion has first inner leads connected to the first outer leads and second inner leads connected to the second outer leads. At least either the first or second inner leads are routed in the element-mounting region. An insulation resin is filled in the gaps between the inner leads located on the element-mounting region. A semiconductor device is configured with semiconductor elements mounted on both the top and bottom surfaces of the lead frame.

A wiring board includes a first wiring layer, a high-speed wiring disposed in the first wiring layer, a second wiring layer, and a signal wiring disposed in the second wiring layer. The signal wiring transmits a signal slower than that through the high-speed wiring. A third wiring layer between the first and second wiring layers includes a power supply wiring and/or a ground wiring, which is not disposed in a portion where a land of the first wiring layer and the signal wiring do not overlap. The power supply wiring and/or the ground wiring overlap the signal wiring in a portion where the land of the first wiring layer and the signal wiring overlap each other.

A semiconductor package includes a substrate, a plurality of semiconductor chips stacked on the substrate, and a plurality of bonding layers bonded to lower surfaces of the plurality of semiconductor chips. The plurality of bonding layers may be divided into a plurality of groups, each having different physical properties depending on a distance from the substrate.

A semiconductor package includes a package substrate, a die stack having a first sub-stack part and a second sub-stack part, an interface chip, and a bonding wire structure. The bonding wire structure includes a first signal wire connecting first signal die pads included in the first sub-stack part to each other, a first signal extension wire connecting the first signal wire to the interface chip, a second signal wire connecting second signal die pads included in the first sub-stack part to each other, a second signal extension wire connecting the second signal wire to the interface chip, an interpose wire connecting interpose die pads included in the first and second sub-stack parts to each other and electrically connecting the interpose die pads to the interface chip, and a shielding wire branched from the interpose wire.

A semiconductor package includes a first sub-semiconductor device, an interposer, and a second sub-semiconductor device stacked on each other, and a heat sink covering the second sub-semiconductor device. The first sub-semiconductor device includes a first substrate and a first semiconductor chip. The interposer includes a dielectric layer, a thermal conductive layer in contact with a bottom surface of the dielectric layer, a first thermal conductive pad in contact with a top surface of the dielectric layer, and thermal conductive vias penetrating the dielectric layer to connect the thermal conductive layer to the first thermal conductive pad. A bottom surface of the thermal conductive layer is adjacent to and connected to a top surface of the first semiconductor chip. The second sub-semiconductor device is disposed on the dielectric layer without overlapping the first thermal conductive pad. The heat sink further covers the first thermal conductive pad to be connected thereto.

A solid state drive (SSD) device, including a substrate; a first buffer chip disposed on the substrate; a second buffer chip disposed on the first buffer chip; a plurality of first nonvolatile memory chips connected to the second buffer chip through wire bonding; a controller configured to transmit a control signal to the plurality of first nonvolatile memory chips through a first channel; and a first redistribution layer disposed in the substrate and configured to electrically connect the first channel to the first buffer chip, wherein the first buffer chip is connected to the first redistribution layer through flip chip bonding, and the second buffer chip is connected to the first redistribution layer through a first wire.

A method of determining a bonding status between a wire and at least one bonding location of a workpiece is provided. The method includes the steps of: (a) bonding a portion of a wire to a bonding location of a workpiece using a bonding tool of a wire bonding machine; (b) determining a motion profile of the bonding tool for determining if the portion of the wire is bonded to the bonding location, the motion profile being configured to result in the wire being broken during the motion profile if the portion of the wire is not bonded to the bonding location; and (c) moving the bonding tool along the motion profile to determine if the portion of the wire is bonded to the bonding location. Other methods of determining a bonding status between a wire and at least one bonding location of a workpiece are also provided.

Disclosed is a data storage device including a controller and a multi-stack chip package, and a method of operating a data storage device. The multi-stack chip package includes a first semiconductor chip arranged on a package substrate, a second semiconductor chip arranged on the first semiconductor chip, and a third semiconductor chip is arranged between the first and second semiconductor chips. The controller can control the first to third semiconductor chips by using a feature parameter measured from each semiconductor chip and a target value that may be originally designed by a memory vendor.

A semiconductor package includes a package substrate, a lower package structure on the package substrate that includes a mold substrate, a semiconductor chip in the mold substrate having chip pads exposed through the mold substrate, spacer chips in the mold substrate and spaced apart from the semiconductor chip, and a redistribution wiring layer on the mold substrate that has redistribution wirings electrically connected to the chip pads, first and second stack structures on the lower package structure spaced apart from each other, each of the first and second stack structures including stacked memory chips, and a molding member covering the lower package structure and the first and second stack structures, wherein the mold substrate includes a first covering portion covering side surfaces of the semiconductor chip and the spacer chips, and a second covering portion covering a lower surface of the semiconductor chip.

A semiconductor storage device includes a first chip and a second chip. The first chip includes a semiconductor substrate, transistors, a first interconnect, and first bonding electrodes. The second chip includes a memory cell array and second bonding electrodes. The second bonding electrodes are bonded to the first bonding electrodes. The first chip or the second chip has bonding pad electrodes. The second bonding electrodes include third bonding electrodes and fourth bonding electrodes. The third and fourth bonding electrodes overlap the memory cell array. The third bonding electrodes are in a current pathway between the memory cell array and the transistors whereas the fourth bonding electrodes are not in such a current pathway. The first interconnect is electrically connected to a bonding pad electrode and a fourth bonding electrode directly, without a current path via any one of transistors.