A semiconductor device has a first substrate and a first electrical component disposed over the first substrate. A first support frame is disposed over the first substrate. The first support frame has a horizontal support channel extending across the first substrate and a vertical support brace extending from the horizontal support channel to the first substrate. The first support frame can have a vertical shielding partition extending from the horizontal support channel to the first substrate. An encapsulant is deposited over the first electrical component and first substrate and around the first support frame. A second electrical component is disposed over the first electrical component. A second substrate is disposed over the first support frame. A second electrical component is disposed over the second substrate. A third substrate is disposed over the second substrate. A second support frame is disposed over the second substrate.

A semiconductor package includes a semiconductor die and an encapsulant layer. A mark is formed on a surface of the encapsulant layer. A damage barrier layer is disposed between the mark and the semiconductor die. The damage barrier layer blocks the propagation of laser light used to form the mark from reaching the semiconductor die.

A metal base plate is rectangular in plan view, has a joining region set on a front surface, and has a center line, which is parallel to a pair of short sides that face each other, set in a middle interposed between the pair of short sides. A ceramic circuit board includes a ceramic board that is rectangular in plan view, a circuit pattern that is formed on a front surface of the ceramic board and has a semiconductor chip joined thereto, and a metal plate that is formed on a rear surface of the ceramic board and is joined to the joining region by solder. Here, the solder contains voids and is provided with a stress relieving region at one edge portion that is away from the center line. A density of voids included in the stress relieving region is higher than other regions of the solder.

Damage to a joint part of a terminal of an electronic component mounted on a substrate is detected. The substrate includes a base material unit, a land, and a light detection unit. The land included in the substrate is arranged with a stress light emitting body configured to emit light in accordance with stress, includes a transparent member, and is joined with a terminal of an element arranged in the base material unit included in the substrate. The light detection unit included in the substrate is arranged between the base material unit and the land included in the substrate, and detects light from the stress light emitting body.

A semiconductor structure and a manufacturing method thereof are provided. The method includes the following steps. A plurality of conductive balls is placed over a circuit substrate, where each of the conductive balls is placed over a contact area of one of a plurality of contact pads that is accessibly revealed by a patterned mask layer. The conductive balls are reflowed to form a plurality of external terminals with varying heights connected to the contact pads of the circuit substrate, where a first external terminal of the external terminals formed in a first region of the circuit substrate and a second external terminal of the external terminals formed in a second region of the circuit substrate are non-coplanar.

A semiconductor package and a method of forming the same are provided. The semiconductor package includes: a semiconductor substrate having a front side and a back side, the semiconductor substrate having a chip area and a dummy area; a front structure below the front side, and including an internal circuit, an internal connection pattern, a guard pattern, and a front insulating structure; a rear protective layer overlapping the chip area and the dummy area, and a rear protrusion pattern on the rear protective layer and overlapping the dummy area, the rear protective layer and the rear protrusion pattern being on the back side; a through-electrode structure penetrating through the chip area and the rear protective layer, and electrically connected to the internal connection pattern; and a rear pad electrically connected to the through-electrode structure. The internal circuit and the internal connection pattern are below the chip area, and the guard pattern is below the chip area adjacent to the dummy area.

A semiconductor package includes a package substrate, a semiconductor stack on the package substrate, a passive device on the package substrate and spaced apart from the semiconductor stack, and a stiffener on the package substrate and extending around an outer side of the semiconductor stack. The stiffener includes a first step surface extends over the passive device. A width of a bottom surface of the stiffener is smaller than a width of a top surface of the stiffener.

A semiconductor package includes a base substrate; an interposer substrate including a semiconductor substrate having a first surface facing the base substrate and a second surface, opposing the first surface, and a passivation layer on at least a portion of the first surface; a plurality of connection bumps between the base substrate and the interposer substrate; an underfill resin in a space between the base substrate and the interposer substrate; and a first semiconductor chip and a second semiconductor chip on the interposer substrate. The interposer substrate has a first region, in which the plurality of connection bumps are included, and a second region and a third region adjacent a periphery of the first region, and the passivation layer is in the second region and includes a first embossed pattern in the second region.

This method for producing a semiconductor device comprises: a first step wherein a plurality of semiconductor chips are affixed onto a supporting substrate such that circuit surfaces of the semiconductor chips face the supporting substrate; a second step wherein a plurality of sealed layers are formed at intervals by applying the sealing resin onto the semiconductor chips by three-dimensional modeling method, each sealed layer containing one or more semiconductor chips embedded in a sealing resin; a third step wherein the sealed layers are cured or solidified; and a fourth step wherein sealed bodies are obtained by separating the cured or solidified sealed layers from the supporting substrate.

A semiconductor device assembly including a substrate, a semiconductor device, a stiffener member, and mold compound. The stiffener member is tuned, or configured, to reduce and/or control the shape of warpage of the semiconductor device assembly at an elevated temperature. The stiffener member may be placed on the substrate, on the semiconductor device, and/or on the mold compound. A plurality of stiffener members may be used. The stiffener members may be positioned in a predetermined pattern on a component of the semiconductor device assembly. A stiffener member may be used so that the warpage of a first semiconductor device substantially corresponds to the warpage of a second semiconductor device at an elevated temperature. The stiffener member may be tuned by providing the member with a desired coefficient of thermal expansion (CTE). The desired CTE may be based on the individual CTEs of the components of a semiconductor device assembly.