Chip packages and method of manufacturing the same are disclosed. In an embodiment, a chip package may include: a redistribution layer (RDL); a first chip including a plurality of first contact pads, the plurality of first contact pads facing the RDL; a second chip disposed between the first chip and the redistribution layer (RDL) wherein a portion of the first chip is disposed outside a lateral extent of the second chip; and a conductive via laterally separated from the second chip, the conductive via extending between the RDL and a first contact pad of the plurality of first contact pads, the first contact pad located in the portion of the first chip disposed outside the lateral extent of the second chip.

A semiconductor device includes an integrated circuit, an outer seal ring, and an inner seal ring. The outer seal ring forms a first closed loop surrounding the integrated circuit. The inner seal ring is between the outer seal ring and the integrated circuit. The inner seal ring has a first seal portion surrounding the integrated circuit and a second seal portion spaced apart from the first seal portion, a first connector interconnecting the first seal portion and the second seal portion, and a second connector spaced apart from the first connector and interconnecting the first seal portion and the second seal portion. The first seal portion, the second seal portion, the first connector, and the second connector form a second closed loop.

The present embodiments provides a chip, including a carrier, a redistribution structure, and multiple packaging function modules, where the multiple packaging function modules each have at least a part wrapped by a colloid, and are fastened to the redistribution structure side by side; the redistribution structure is fastened to the carrier, and the redistribution structure includes one or more redistribution metal layers; the redistribution metal layer communicatively connects the multiple packaging function modules and the carrier. The redistribution structure further includes one or more interconnect metal layers, and the interconnect metal layer is communicatively connected to at least two packaging function modules so as to provide a signal path between the at least two packaging function modules. In the chip, two packaging function modules are placed on the carrier side by side, and a signal path is established between the two packaging function modules by using the redistribution structure.

A package structure includes at least one die, an antenna element, and at least one through interlayer via. The antenna element is located on the at least one die. The at least one through interlayer via is located between the antenna element and the at least one die, wherein the antenna element is electrically connected to the at least one die through the at least one through interlayer via.

A package structure and the method thereof are provided. At least one die is molded in a molding compound. A ground plate is located on a backside surface of the die, a first surface of the ground plate is exposed from the molding compound and a second surface of the ground plate is covered by the molding compound. The first surface of the ground plate is levelled and coplanar with a third surface of the molding compound. A connecting film is located between the backside surface of the die and the second surface of the ground plate. The die, the molding compound and the ground plate are in contact with the connecting film. Through interlayer vias (TIVs) are molded in the molding compound, and at least one of the TIVs is located on and physically contacts the second surface of the ground plate.

According to various aspects, exemplary embodiments are disclosed of board level shields with virtual grounding capability. In an exemplary embodiment, a board level shield includes one or more resonators configured to be operable for virtually connecting the board level shield to a ground plane or a shielding surface. Also disclosed are exemplary embodiments of methods relating to making board level shields having virtual grounding capability. Additionally, exemplary embodiments are disclosed of methods relating to providing shielding for one or more components on a substrate by using a board level shield having virtual grounding capability. Further exemplary embodiments are disclosed of methods relating to making system in package (SiP) or system on chip (SoC) shielded modules and methods relating to providing shielding for one or more components of SiP or SoC module.

A semiconductor device has a substrate with a plurality of conductive vias formed through the substrate in an offset pattern. An electrical component is disposed in a die attach area over a first surface of the substrate. The conductive vias are formed around the die attach area of the substrate. A first conductive layer is formed over the first surface of the substrate, and a second conductive layer is formed over the second surface. An encapsulant is deposited over the substrate and electrical component. The substrate is singulated through the conductive vias. A first conductive via has a greater exposed surface area than a second conductive via. A shielding layer is formed over the electrical component and in contact with a side surface of the conductive vias. The shielding layer may extend over a second surface of substrate opposite the first surface of the substrate.

A semiconductor device and method for forming the semiconductor device is provided. The semiconductor device includes an integrated circuit having through vias adjacent to the integrated circuit die, wherein a molding compound is interposed between the integrated circuit die and the through vias. The through vias have a projection extending through a patterned layer, and the through vias may be offset from a surface of the patterned layer. The recess may be formed by selectively removing a seed layer used to form the through vias.

Discussed generally herein are devices that include high density interconnects between dice and techniques for making and using those devices. In one or more embodiments a device can include a bumpless buildup layer (BBUL) substrate including a first die at least partially embedded in the BBUL substrate, the first die including a first plurality of high density interconnect pads. A second die can be at least partially embedded in the BBUL substrate, the second die including a second plurality of high density interconnect pads. A high density interconnect element can be embedded in the BBUL substrate, the high density interconnect element including a third plurality of high density interconnect pads electrically coupled to the first and second plurality of high density interconnect pads.

A method includes bonding a first package to a second package to form a third package. The first package is an Integrated Fan-Out (InFO) package including a plurality of package components, and an encapsulating material encapsulating the plurality of package components therein. The plurality of package components include device dies. The method further includes placing at least a portion of the third package into a recess in a Printed Circuit Board (PCB). The recess extends from a top surface of the PCB to an intermediate level between the top surface and a bottom surface of the PCB. Wire bonding is performed to electrically connect the third package to the PCB.