A printed circuit board includes an insulating layer; and an external connection pad embedded in the insulating layer and having one surface exposed. The external connection pad may include a base pad portion having a first pattern portion in contact with a side surface of the insulating layer and having a first width, and a second pattern portion protruding from the first pattern portion and having a second width smaller than the first width, the second pattern portion having a gap with the side surface of the insulating layer, and a surface treatment layer disposed in the gap between the second pattern portion and the insulating layer and extending on an upper surface of the second pattern portion.

An apparatus includes a substrate for mounting an integrated circuit. The substrate includes a primary layer including a first surface that is a first external surface of the substrate. The substrate includes an inner layer that is located below the primary layer and including a second surface. A portion of the second surface of the inner layer is exposed via an open area associated with the primary layer. The inner layer includes a first multiple of wire bond pads that are exposed via the open area associated with the primary layer.

A MEMS pressure sensor packaged with a molding compound. The MEMS pressure sensor features a lead frame, a MEMS semiconductor die, a second semiconductor die, multiple pluralities of bonding wires, and a molding compound. The MEMS semiconductor die has an internal chamber, a sensing component, and apertures. The MEMS semiconductor die and the apertures are exposed to an ambient atmosphere. A method is desired to form a MEMS pressure sensor package that reduces defects caused by mold flashing and die cracking. Fabrication of the MEMS pressure sensor package comprises placing a lead frame on a lead frame tape; placing a MEMS semiconductor die adjacent to the lead frame and on the lead frame tape with the apertures facing the tape and being sealed thereby; attaching a second semiconductor die to the MEMS semiconductor die; attaching pluralities of bonding wires to form electrical connections between the MEMS semiconductor die, the second semiconductor die, and the lead frame; and forming a molding compound.

In an embodiment, a package includes a first package structure including a first die having a first active side and a first back-side, the first active side including a first bond pad and a first insulating layer a second die bonded to the first die, the second die having a second active side and a second back-side, the second active side including a second bond pad and a second insulating layer, the second active side of the second die facing the first active side of the first die, the second insulating layer being bonded to the first insulating layer through dielectric-to-dielectric bonds, and a conductive bonding material bonded to the first bond pad and the second bond pad, the conductive bonding material having a reflow temperature lower than reflow temperatures of the first and second bond pads.

A semiconductor device comprises a semiconductor die and an integrated capacitor formed over the semiconductor die. The integrated capacitor is configured to receive a high voltage signal. A transimpedance amplifier is formed in the semiconductor die. An avalanche photodiode is disposed over or adjacent to the semiconductor die. The integrated capacitor is coupled between the avalanche photodiode and a ground node. A resistor is coupled between a high voltage input and the avalanche photodiode. The resistor is an integrated passive device (IPD) formed over the semiconductor die. A first terminal of the integrated capacitor is coupled to a ground voltage node. A second terminal of the integrated capacitor is coupled to a voltage greater than 20 volts. The integrated capacitor comprises a plurality of interdigitated fingers in one embodiment. In another embodiment, the integrated capacitor comprises a plurality of vertically aligned plates.

Semiconductor die assemblies with molded semiconductor dies, and associated methods and systems are disclosed. In some embodiments, a semiconductor die assembly includes a package substrate and a controller die attached to the package substrate. The semiconductor die assembly comprises a mold structure including the controller die and having a surface facing away from the package substrate. The controller die may be completely encased within the mold structure. Further, one or more stacks of semiconductor dies (e.g., memory dies) are attached to the surface of the mold structure. Accordingly, the semiconductor die assembly does not include support structures for the stacks of semiconductor dies attached above the controller die.

A printed circuit board includes an insulating layer; and an external connection pad embedded in the insulating layer and having one surface exposed. The external connection pad may include a base pad portion having a first pattern portion in contact with a side surface of the insulating layer and having a first width, and a second pattern portion protruding from the first pattern portion and having a second width smaller than the first width, the second pattern portion having a gap with the side surface of the insulating layer, and a surface treatment layer disposed in the gap between the second pattern portion and the insulating layer and extending on an upper surface of the second pattern portion.

Various embodiments of the present application are directed towards a pad with high strength and bondability. In some embodiments, an integrated chip comprises a substrate, an interconnect structure, a pad, and a conductive structure. The interconnect structure adjoins the substrate and comprises wires and vias. The wires and the vias are stacked between the pad and the substrate. The conductive structure (e.g., a wire bond) extends through the substrate to the pad. By arranging the wires and the vias between the pad and the substrate, the pad may be inset into a passivation layer of the interconnect structure and the passivation layer may absorb stress on the pad. Further, the pad may contact the wires and the vias at a top wire level. A thickness of the top wire level may exceed a thickness of other wire levels, whereby the top wire level may be more tolerant to stress.

The semiconductor module includes: a heat dissipation board including first to third wiring patterns; a first metal plate on the first wiring pattern, a second metal plate on the second wiring pattern, a first semiconductor chip and a first intermediate board which are on the first metal plate, a second semiconductor chip and a second intermediate board which are on the second metal plate. A first metal film on the first intermediate board is electrically connected to the first semiconductor chip and the second metal plate, and a second metal film on the second intermediate board is electrically connected to the second semiconductor chip and the third wiring pattern.

Various embodiments of the present application are directed towards a pad with high strength and bondability. In some embodiments, an integrated chip comprises a substrate, an interconnect structure, a pad, and a conductive structure. The interconnect structure adjoins the substrate and comprises wires and vias. The wires and the vias are stacked between the pad and the substrate. The conductive structure (e.g., a wire bond) extends through the substrate to the pad. By arranging the wires and the vias between the pad and the substrate, the pad may be inset into a passivation layer of the interconnect structure and the passivation layer may absorb stress on the pad. Further, the pad may contact the wires and the vias at a top wire level. A thickness of the top wire level may exceed a thickness of other wire levels, whereby the top wire level may be more tolerant to stress.