A method of fabricating a bridged multi-chip assembly structure includes providing a carrier substrate. The method further includes arranging a plurality of chips on the carrier substrate in a predetermined layout. Each chip has a front surface including a set of terminals formed thereon. The method further includes depositing a molding material between the plurality of chips and on the carrier substrate. The method further includes removing the carrier substrate from the plurality of chips fixed by the molding material. The method further includes bonding a bridge chip to corresponding sets of terminals of at least two chips of the plurality of chips fixed by the molding material.

A support substrate includes an insulating core layer, an electrically conductive layer over the insulating core layer and a solder mask layer over the electrically conductive layer. A back side of an integrated circuit chip is mounted to an upper surface of the support substrate at a die attach location. The upper surface of the support substrate includes a cavity located within the die attach location, where the cavity extends under the back side of the integrated circuit chip. The cavity is defined by an area where the solder mask layer and at least a portion of the electrically conductive layer have been removed. Bonding wires connect connection pads on a front side of the integrated circuit chip to connection pad on the upper surface of the support substrate.

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 package includes a logic die surrounded by a molding compound; a memory die disposed in proximity to the logic die; a plurality of vias around the logic die for electrically connecting the logic die to the memory die. Each of the plurality of vias has an oval shape or a rectangular shape when viewed from above. The vias have a horizontal pitch along a first direction and a vertical pitch along a second direction. The vertical pitch is greater than the horizontal pitch.

Embodiments presented in this disclosure generally relate to techniques for interconnecting integrated circuits. More specifically, embodiments disclosed herein provide a back mounted interposer (BMI) to facilitate interconnecting of integrated circuits. One example apparatus includes an integrated circuit, an interposer, and a circuit board, at least a portion of the circuit board being disposed between the integrated circuit and the interposer, where the circuit board is configured to provide electrical connection between the interposer and the integrated circuit via connection elements on a first surface of the interposer. The apparatus also includes an interface on a second surface of the interposer, the interface being configured to provide signals from the integrated circuit to an electrical component.

A package structure includes first/second/third package components, a thermal interface material (TIM) structure overlying the first package component opposite to the second package component, and a heat dissipating component disposed on the third package component and thermally coupled to the first package component through the TIM structure. The first package component includes semiconductor dies and an insulating encapsulation encapsulating the semiconductor dies, the second package component is interposed between the first and third package components, and the semiconductor dies are electrically coupled to the third package component via the second package component. The TIM structure includes a dielectric dam and thermally conductive members including a conductive material, disposed within areas confined by the dielectric dam, and overlying the semiconductor dies. A manufacturing method of a package structure is also provided.

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 assembly package is provided. The semiconductor package assembly includes a system-on-chip (SOC) package, a memory package and a heat spreader. The SOC package includes a logic die and a first substrate. The logic die has pads on it. The first substrate is electrically connected to the logic die by the pads. The memory package includes a second substrate and a memory die. The second substrate has a top surface and a bottom surface. The memory die is mounted on the top surface of the second substrate and is electrically connected to the second substrate using bonding wires. The heat spreader is disposed between the SOC package and the memory package, wherein the heat spreader is in contact with a back surface of the logic die away from the pads.

A semiconductor package includes a package board, at least one semiconductor chip disposed on the package board, a molding member disposed on the package board and at least partially surrounding the at least one semiconductor chip, and a heat dissipation member disposed on the at least one semiconductor chip and the molding member. The molding member has first region in which a plurality of uneven structures are disposed, and a second region spaced apart from an external region by the plurality of uneven structures. The plurality of uneven structures protrude to a predetermined height away from the semiconductor chip, the molding member, and the heat dissipation member, and may be formed as a part of the head dissipation member, or formed separately.

Provided is a package-on-package (PoP). The PoP includes a lower package, an upper package on the lower package, an interposer substrate disposed between the lower package and the upper package, and a plurality of balls connecting the interposer substrate to the upper package, in which the lower package includes a first substrate, and a first die and a second die disposed side by side in a horizontal direction, on the first substrate, in which the upper package includes a second substrate, a third die on the second substrate, and a plurality of ball pads disposed on a surface of the second substrate, the interposer substrate comprises on a surface thereof a plurality of ball lands to which a plurality of balls are attached, and at least some of the plurality of ball lands overlap the first die and the second die in a vertical direction that intersects the horizontal direction.