Abstract: A securing mechanism is provided for facilitating attaching a heat dissipation element. The securing mechanism includes a first fixing part, a second fixing part, a first arm and a second arm. The first arm and the second arm are connected with the first fixing part and the second fixing part. A first bent structure is protruded from the first arm and toward the second arm. A second bent structure is protruded from the second arm and toward the first arm. The securing mechanism is fixed on the heat dissipation element through the first fixing part and the second fixing part. The heat dissipation element is pressed by the first bent structure and the second bent structure. Consequently, the heat dissipation element is attached on the heat source.

Abstract: A structure includes an encapsulating material, and a coil including a through-conductor. The through-conductor is in the encapsulating material, with a top surface of the through-conductor coplanar with a top surface of the encapsulating material, and a bottom surface of the through-conductor coplanar with a bottom surface of the encapsulating material. A metal plate is underlying the encapsulating material. A slot is in the metal plate and filled with a dielectric material. The slot has a portion overlapped by the coil.

Abstract: A semiconductor structure has an integrated circuit component, a conductive contact pad, a seal ring structure, a conductive via, a ring barrier, and a mold material. The conductive contact pad is disposed on and electrically connected with the integrated circuit component. The seal ring structure is disposed on the integrated circuit component and surrounding the conductive contact pad. The conductive via is disposed on and electrically connected with the conductive contact pad. The ring barrier is disposed on the seal ring structure. The ring barrier surrounds the conductive via. The mold material covers side surfaces of the integrated circuit component. A semiconductor manufacturing process is also provided.

Abstract: A structure includes a device die, and an encapsulating material encapsulating the device die therein. The encapsulating material has a top surface coplanar with a top surface of the device die, and a cavity in the encapsulating material. The cavity penetrates through the encapsulating material.

Abstract: A method of manufacturing a semiconductor structure includes providing a transceiver, forming a molding to surround the transceiver, forming a plurality of recesses extending through the molding, disposing a conductive material into the plurality of recesses to form a plurality of vias, disposing and patterning an insulating layer over the molding, the plurality of vias and the transceiver, and forming a redistribution layer (RDL) over the insulating layer, wherein the RDL comprises an antenna disposed over the insulating layer and a dielectric layer covering the antenna, and a portion of the antenna is extended through the insulating layer and is electrically connected with the transceiver.

Abstract: A securing mechanism is provided for facilitating attaching a heat dissipation element. The securing mechanism includes a first fixing part, a second fixing part, a first arm and a second arm. The first arm and the second arm are connected with the first fixing part and the second fixing part. A first bent structure is protruded from the first arm and toward the second arm. A second bent structure is protruded from the second arm and toward the first arm. The securing mechanism is fixed on the heat dissipation element through the first fixing part and the second fixing part. The heat dissipation element is pressed by the first bent structure and the second bent structure. Consequently, the heat dissipation element is attached on the heat source.

Abstract: A method includes measuring a first calibration kit in a wafer to obtain a first performance data. The wafer includes a substrate, and a plurality of dielectric layers over the substrate. The first calibration kit includes a first passive device over the plurality of dielectric layers, wherein substantially no metal feature is disposed in the plurality of dielectric layers and overlapped by the first passive device. The method further includes measuring a second calibration kit in the wafer to obtain a second performance data. The second calibration kit includes a second passive device identical to the first device and over the plurality of dielectric layers, and dummy patterns in the plurality of dielectric layers and overlapped by the second passive device. The first performance data and the second performance data are de-embedded to determine an effect of metal patterns in the plurality of dielectric layers to overlying passive devices.

Abstract: A system and method for providing and manufacturing an inductor is provided. In an embodiment similar masks are reutilized to form differently sized inductors. For example, a two turn inductor and a three turn inductor may share masks for interconnects and coils, while only masks necessary for connections between the interconnects and coils may need to be newly developed.

Abstract: A structure includes a device die, and an encapsulating material encapsulating the device die therein. The encapsulating material has a top surface coplanar with a top surface of the device die, and a cavity in the encapsulating material. The cavity penetrates through the encapsulating material.

Abstract: A semiconductor structure includes a transceiver configured to communicate with a device, a molding surrounding the transceiver, a via extending through the molding, an insulating layer disposed over the molding, the via and the transceiver, and a redistribution layer (RDL) disposed over the insulating layer and comprising an antenna and a dielectric layer surrounding the antenna, wherein a portion of the antenna is extended through the insulating layer and the molding to electrically connect with the transceiver.

Abstract: An optical sensing system is disclosed. The optical sensing system includes a printed circuit board (PCB), a supporter and an optical sensor. The PCB includes a top surface, a bottom surface and a through cavity, wherein the through cavity extends downwardly from the top surface to the bottom surface. The supporter has a top surface and a bottom surface. The optical sensor is bonded and coupled to the top surface of the supporter, wherein the optical sensor includes a primary optic structure. Wherein the supporter is flipped over and bonded to the PCB with the top surface facing the through cavity, so that the optical sensor is coupled to the PCB and at least partially extends to the through cavity. Associated electronic devices are also disclosed.

Abstract: A system and method for providing and manufacturing an inductor is provided. In an embodiment similar masks are reutilized to form differently sized inductors. For example, a two turn inductor and a three turn inductor may share masks for interconnects and coils, while only masks necessary for connections between the interconnects and coils may need to be newly developed.

Abstract: A method of manufacturing a semiconductor device includes: receiving a first substrate with a surface; receiving a second substrate; determining a pad array on the surface of the first substrate, wherein the pad array includes a first type pad and a second type pad; forming a via pattern underlying the pad array in the first substrate according to the location of each via, wherein the first type pad in the pad array is directly contacting a via of the via pattern and the second type pad in the pad array is clear of any via of the via pattern; laterally connecting the second type pad with a conductive trace, wherein the conductive trace connects to another via that is same level with the via contacting the first type pad; and disposing a first conductive bump and a second conductive bump between the first substrate and the second substrate.

Abstract: Coil structures and methods of forming are provided. The coil structure includes a substrate. A plurality of coils is disposed over the substrate, each coil comprising a conductive element that forms a continuous spiral having a hexagonal shape in a plan view of the coil structure. The plurality of coils is arranged in a honeycomb pattern, and each conductive element is electrically connected to an external electrical circuit.

Abstract: A method of manufacturing a semiconductor structure include: providing a die including a die pad disposed over the die; disposing a conductive member over the die pad of the die; forming a molding surrounding the die and the conductive member; disposing a dielectric layer over the molding, the die and the conductive member; and forming an interconnect structure including a land portion and a plurality of via portions. The land portion is disposed over the dielectric layer, the plurality of via portions are disposed over the conductive member and protruded from the land portion to the conductive member through the dielectric layer, and each of the plurality of via portions at least partially contacts with the conductive member.

Abstract: A semiconductor device includes a first molding layer; a second molding layer formed over the first molding layer; a first conductive coil including a first portion continuously formed in the first molding layer and a second portion continuously formed in the second molding layer, wherein the first and the second portions are laterally displaced from each other; and a second conductive coil formed in the second molding layer, wherein the second conductive coil is interweaved with the second portion of the first conductive coil in the second molding layer.

Abstract: A semiconductor structure has an integrated circuit component, a conductive contact pad, a seal ring structure, a conductive via, a ring barrier, and a mold material. The conductive contact pad is disposed on and electrically connected with the integrated circuit component. The seal ring structure is disposed on the integrated circuit component and surrounding the conductive contact pad. The conductive via is disposed on and electrically connected with the conductive contact pad. The ring barrier is disposed on the seal ring structure. The ring barrier surrounds the conductive via. The mold material covers side surfaces of the integrated circuit component. A semiconductor manufacturing process is also provided.

Abstract: A method includes measuring a first calibration kit in a wafer to obtain a first performance data. The wafer includes a substrate, and a plurality of dielectric layers over the substrate. The first calibration kit includes a first passive device over the plurality of dielectric layers, wherein substantially no metal feature is disposed in the plurality of dielectric layers and overlapped by the first passive device. The method further includes measuring a second calibration kit in the wafer to obtain a second performance data. The second calibration kit includes a second passive device identical to the first device and over the plurality of dielectric layers, and dummy patterns in the plurality of dielectric layers and overlapped by the second passive device. The first performance data and the second performance data are de-embedded to determine an effect of metal patterns in the plurality of dielectric layers to overlying passive devices.

Abstract: A package includes a device die, and an encapsulating material encapsulating the device die therein. The encapsulating material has a top surface coplanar with a top surface of the device die. A coil extends from the top surface to a bottom surface of the encapsulating material, and the device die is in the region encircled by the coil. At least one dielectric layer is formed over the encapsulating material and the coil. A plurality of redistribution lines is in the at least one dielectric layer. The coil is electrically coupled to the device die through the plurality of redistribution lines.

Abstract: A conductive terminal on an integrated circuit is provided. The conductive terminal includes a conductive pad, a dielectric layer, and a conductive via. The conductive pad is disposed on and electrically to the integrated circuit. The dielectric layer covers the integrated circuit and the conductive pad, the dielectric layer includes a plurality of contact openings arranged in array, and the conductive pad is partially exposed by the contact openings. The conductive via is disposed on the dielectric layer and electrically connected to the conductive pad through the contact openings. The conductive via includes a plurality of convex portions arranged in array. The convex portions are distributed on a top surface of the conductive via, and the convex portions are corresponding to the contact openings.