A package structure is provided. The package structure includes an interposer substrate including an insulating structure, a conductive pad, a first conducive line, and a first conductive via structure. The package structure includes an electronic device bonded to the conductive pad. The package structure includes a chip structure bonded to the first end portion of the first conductive via structure. The package structure includes a first conductive bump connected between the chip structure and the first end portion of the first conductive via structure. The first end portion protrudes into the first conductive bump and is in direct contact with the first conductive bump.

One or more implementations of the subject technology may enable a bond-on-pad (BoP) substrate technology that can eliminate the need to utilize a solder-on-pad (SoP) process. Unlike an SoP process, a BoP Process does not require a solder bump to be formed on a bump pad to attach a joint to a bump pad. The size of an opening on a bump pad for a BoP process may be larger than that of an SoP process. A BoP process may use a solder mask having multiple thicknesses and may be thinner near the bump pads. A BoP process may use a joint having a copper pillar and a solder cap. A BoP process can be used with an underfill or a molding compound technology.

Semiconductor devices and semiconductor device packages may include at least one first semiconductor die supported on a first side of a substrate. The at least one first semiconductor die may include a first active surface. A second semiconductor die may be supported on a second, opposite side of the substrate. The second semiconductor die may include a second active surface located on a side of the second semiconductor die facing the substrate. The second semiconductor die may be configured to have higher median power consumption than the at least one first semiconductor die during operation. An electronic system incorporating a semiconductor device package is disclosed, as are related methods.

A substrate having an electronic component embedded therein includes a core structure including a first insulating body and core wiring layers and having a cavity penetrating through a portion of the first insulating body, an electronic component disposed in the cavity, an insulating material covering at least a portion of each of the core structure and the electronic component and disposed in at least a portion of the cavity, a wiring layer disposed on the insulating material, and a build-up structure disposed on the insulating material and including a second insulating body and a build-up wiring layer. A material of the first insulating body has a coefficient of thermal expansion (CTE) less than a CTE of the second insulating body, and the insulating material has a CTE less than a CTE of a material of the second insulating body.

In examples, a semiconductor package comprises a ceramic substrate and first and second metal layers covered by the ceramic substrate. The first metal layer is configured to carry signals at least in a 20 GHz to 28 GHz frequency range. The package comprises a semiconductor die positioned above the first and second metal layers and coupled to the first metal layer. The package comprises a ground shield positioned in a horizontal plane between the semiconductor die and the first metal layer, the ground shield including an orifice above a portion of the first metal layer. The package includes a metal seal ring coupled to a top surface of the ceramic substrate, the metal seal ring having a segment that is vertically aligned with a segment of the ground shield. The segment of the ground shield is between the orifice of the ground shield and a horizontal center of the ground shield. The package comprises a metal lid coupled to a top surface of the metal seal ring.

Flexible devices including conductive traces with enhanced stretchability, and methods of making and using the same are provided. The circuit die is disposed on a flexible substrate. Electrically conductive traces are formed in channels on the flexible substrate to electrically contact with contact pads of the circuit die. A first polymer liquid flows in the channels to cover a free surface of the traces. The circuit die can also be surrounded by a curing product of a second polymer liquid.

In an embodiment, a device includes: a bottom integrated circuit die having a first front side and a first back side; a top integrated circuit die having a second front side and a second back side, the second back side being bonded to the first front side, the top integrated circuit die being free from through substrate vias (TSVs); a dielectric layer surrounding the top integrated circuit die, the dielectric layer being disposed on the first front side, the dielectric layer and the bottom integrated circuit die being laterally coterminous; and a through via extending through the dielectric layer, the through via being electrically coupled to the bottom integrated circuit die, surfaces of the through via, the dielectric layer, and the top integrated circuit die being planar.

A package structure and a method of forming the same are provided. The package structure includes a package substrate, an interposer substrate, a first semiconductor device, and a second semiconductor device. The interposer substrate is disposed over the package substrate and includes a silicon substrate. The interposer substrate has a bottom surface facing and adjacent to the package substrate, a top surface opposite the bottom surface, and a cavity formed on the top surface. The first semiconductor device is disposed on the top surface of the interposer substrate. The second semiconductor device is received in the cavity and electrically connected to the first semiconductor device and/or the interposer substrate.

The present disclosure provides a semiconductor module comprising a semiconductor device removably pressed-fit in a cavity formed in a printed circuit board and methods for manufacturing the same. The semiconductor device and the cavity of the printed circuit board can cooperate with each other and act as an electrical plug and an electrical socket respectively. Soldering the semiconductor device on the printed circuit board can be avoided. Therefore, the packaging process can be more flexible and reliability issues with solder joints can be eliminated. Moreover, heatsink can be mounted on top and/or bottom of the semiconductor device after being received in the cavity of the printed circuit board. Thermal dissipation efficiency can be greatly enhanced.

A direct bonded heterogeneous integration (DBHi) device includes a substrate including a trench formed in a top surface of the substrate. The DBHi device further includes a first chip coupled to the substrate on a first side of the trench by a plurality of first interconnects. The DBHi device further includes a second chip coupled to the substrate on a second side of the trench by a plurality of second interconnects. The second side of the trench is arranged opposite the first side of the trench. The DBHi device further includes a bridge coupled to the first chip and to the second chip by a plurality of third interconnects such that the bridge is suspended in the trench. The DBHi device further includes a non-conductive paste material surrounding the plurality of third interconnects to further couple the bridge to the first chip and to the second chip.