A semiconductor package includes a first interconnect substrate on a first redistribution substrate and having a first opening penetrating the first interconnect substrate. A first semiconductor chip is on the first redistribution substrate and the first opening of the first interconnect substrate. A second redistribution substrate is on the first interconnect substrate and the first semiconductor chip. A second interconnect substrate is on the second redistribution substrate and has a second opening penetrating the second interconnect substrate. A second semiconductor chip is on the second redistribution substrate and in the second opening of the second interconnect substrate.

A technique of assembling a plurality of chips is disclosed. A plurality of chip layers, each of which includes at least one chip block, is prepared. Each chip block includes a plurality of electrodes assigned the same function. The plurality of the chip layers is sequentially stacked with rotation so as to configure at least one stack of overlapping chip blocks. Each stack holds a plurality of groups of vertically arranged electrodes with shifts in horizontal plane. A through hole is formed, for at least one of the groups, into the plurality of the chip layers at least in part so as to expose electrode surfaces of vertically arranged electrodes in the group. The through hole is filled with conductive material.

A method for fabricating a semiconductor chip module and a semiconductor chip package is disclosed. One embodiment provides a first layer, a second layer, and a base layer. The first layer is disposed on the base layer, and the second layer is disposed on the first layer. A plurality of semiconductor chips is applied above the second layer, and the second layer with the applied semiconductor chips is separated from the first layer.

An electronic module on a flexible planar circuit substrate with a conductor configuration on a first substrate surface and a plurality of electronic components on the opposite, second substrate surface, wherein the components have component contacts, which are electrically connected selectively by way of vias in the circuit substrate and the conductor configuration, wherein the circuit substrate is a thermoplastic polymer and the component contacts are melted or thermally pressed into the second substrate surface in the region of the vias.

A wafer-level system-in-package (WLSiP) package structure is provided. The WLSiP package structure includes a device wafer, an adhesive layer, and a plurality of second chips. The device wafer includes a first front surface having a plurality of first chips integrated therein and a first back surface opposing the first front surface. The adhesive layer is formed on the first front surface of the device wafer and the adhesive layer includes a plurality of through-holes exposing the first front surface. The plurality of second chips are bonded to the device wafer, and the plurality of second chips are bonded with the adhesive layer to cover the plurality of first through-holes in a one-to-one correspondence.

A package structure includes a first redistribution circuit structure, a second redistribution circuit structure, a semiconductor die, a waveguide structure, and an antenna. The semiconductor die is sandwiched between and electrically coupled to the first redistribution circuit structure and the second redistribution circuit structure. The waveguide structure is located aside and electrically coupled to the semiconductor die, wherein the waveguide structure includes a part of the first redistribution circuit structure, a part of the second redistribution circuit structure and a plurality of first through vias each connecting to the part of the first redistribution circuit structure and the part of the second redistribution circuit structure. The antenna is located on the semiconductor die, wherein the second redistribution circuit structure is sandwiched between the antenna and the semiconductor die, and the antenna is electrically communicated with the semiconductor die through the waveguide structure.

A method includes thinning a semiconductor substrate of a device die to reveal through-substrate vias that extend into the semiconductor substrate, and forming a first redistribution structure, which includes forming a first plurality of dielectric layers over the semiconductor substrate, and forming a first plurality of redistribution lines in the first plurality of dielectric layers. The first plurality of redistribution lines are electrically connected to the through-substrate vias. The method further includes placing a first memory die over the first redistribution structure, and forming a first plurality of metal posts over the first redistribution structure. The first plurality of metal posts are electrically connected to the first plurality of redistribution lines. The first memory die is encapsulated in a first encapsulant. A second plurality of redistribution lines are formed over, and electrically connected to, the first plurality of metal posts and the first memory die.

A manufacturing method of a semiconductor apparatus includes preparing an intermediate member that includes a first member having a first substrate comprising a semiconductor element formed thereon, a second member having a second substrate, the second substrate including a part of a circuit electrically connected to the semiconductor element and having a linear expansion coefficient different from that of the first substrate, and a third member having a third substrate showing such a linear expansion coefficient that a difference between itself and the linear expansion coefficient of the first substrate is smaller than a difference between the linear expansion coefficients of the first substrate and the second substrate, and includes bonding the first member and the second member together. A first bonding electrode containing copper electrically connected to the semiconductor element and a second bonding electrode containing copper electrically connected to the circuit are bonded together.

Electronic assembly methods and structures are described. In an embodiment, an electronic assembly method includes bringing together an electronic component and a routing substrate, and directing a large area photonic soldering light pulse toward the electronic component to bond the electronic component to the routing substrate.

A packaged semiconductor device includes a substrate with first and second opposing major surfaces. A stacked semiconductor device structure is connected to the first major surface and includes a plurality of semiconductor die having terminals. Conductive interconnect structures electrically connect the terminals of the semiconductor dies together. The semiconductor dies are stacked together so that the terminals are exposed, and the stacked semiconductor device structure comprises a stepped profile. The conductive interconnect structures comprise a conformal layer that substantially follows the stepped profile.