Abstract: An embodiment is a method including: attaching a first die to a first side of a first component using first electrical connectors, attaching a first side of a second die to first side of the first component using second electrical connectors, attaching a dummy die to the first side of the first component in a scribe line region of the first component, adhering a cover structure to a second side of the second die, and singulating the first component and the dummy die to form a package structure.

Abstract: An embodiment of the disclosure is a structure comprising an interposer. The interposer has a test structure extending along a periphery of the interposer, and at least a portion of the test structure is in a first redistribution element. The first redistribution element is on a first surface of a substrate of the interposer. The test structure is intermediate and electrically coupled to at least two probe pads.

Abstract: Structures and formation methods of a chip package are provided. The chip package includes a substrate, a first chip stack attached to the substrate, and a second chip stack attached to the substrate. The first chip stack and the second chip stack being attached to a same side of the substrate. The chip package further includes a molding compound layer surrounding the first chip stack and the second chip stack. The molding compound layer covers a topmost surface of the first chip stack. A topmost surface of the molding compound layer is substantially coplanar with a topmost surface of the second chip stack.

Abstract: An embodiment is a circuit. The circuit includes active circuitry, a first capacitor, a first fuse, a second capacitor, and a second fuse. The active circuitry has a first power node and a second power node. The first capacitor is coupled to the first fuse serially to form a first segment. The second capacitor is coupled to the second fuse serially to form a second segment. The first segment and the second segment are coupled together in parallel and between the first power node and the second power node.

Abstract: Various embodiments of mechanisms for forming through a three-dimensional integrated circuit (3DIC) structure are provided. The 3DIC structure includes an interposer bonded to a die and a substrate. The interposer has a conductive structure with through silicon vias (TSVs) connected to a patterned metal pad and a conductive structure on opposite ends of the TSVs. The pattern metal pad is embedded with dielectric structures to reduce dishing effect and has regions over TSVs that are free of the dielectric structures. The conductive structure has 2 or more TSVs. By using a patterned metal pad and 2 or more TSVs, the reliability and yield of the conductive structure and the 3DIC structure are improved.

Abstract: An embodiment is a method including: attaching a first die to a first side of a first component using first electrical connectors, attaching a first side of a second die to first side of the first component using second electrical connectors, attaching a dummy die to the first side of the first component in a scribe line region of the first component, adhering a cover structure to a second side of the second die, and singulating the first component and the dummy die to form a package structure.

Abstract: Formation methods of a chip package are provided. The method includes bonding a first chip structure and a second chip structure over a substrate. The method also includes forming a release film to cover top surfaces of the first chip structure and the second chip structure. The method further includes forming a package layer to surround the first chip structure and the second chip structure after the formation of the release film. In addition, the method includes removing the release film such that the top surface of the first chip structure, the top surface of the second chip structure, and a top surface of the package layer are exposed.

Abstract: Structures and formation methods of a chip package are provided. The chip package includes a chip stack including a number of semiconductor dies. The chip package also includes a semiconductor chip, and the semiconductor chip is higher than the chip stack. The chip package further includes a package layer covering a top and sidewalls of the chip stack and sidewalls of the semiconductor chip.

Abstract: A method includes performing a first light-exposure and a second a second light-exposure on a photo resist. The first light-exposure is performed using a first lithograph mask, which covers a first portion of the photo resist. The first portion of the photo resist has a first strip portion exposed in the first light-exposure. The second light-exposure is performed using a second lithograph mask, which covers a second portion of the photo resist. The second portion of the photo resist has a second strip portion exposed in the second light-exposure. The first strip portion and the second strip portion have an overlapping portion that is double exposed. The method further includes developing the photo resist to remove the first strip portion and the second strip portion, etching a dielectric layer underlying the photo resist to form a trench, and filling the trench with a conductive feature.

Abstract: Structures and formation methods of a chip package are provided. The chip package includes a first chip structure and a second chip structure. Heights of the first chip structure and the second chip structure are different. The chip package also includes a package layer covering sidewalls of the first chip structure and sidewalls of the second chip structure. Top surfaces of the first chip structure and the second chip structure are not covered by the package layer.

Abstract: Structures and formation methods of a chip package are provided. The chip package includes a chip stack including a number of semiconductor dies. The chip package also includes a semiconductor chip, and the semiconductor chip is higher than the chip stack. The chip package further includes a package layer covering a top and sidewalls of the chip stack and sidewalls of the semiconductor chip.

Abstract: A method includes performing a first light-exposure and a second a second light-exposure on a photo resist. The first light-exposure is performed using a first lithograph mask, which covers a first portion of the photo resist. The first portion of the photo resist has a first strip portion exposed in the first light-exposure. The second light-exposure is performed using a second lithograph mask, which covers a second portion of the photo resist. The second portion of the photo resist has a second strip portion exposed in the second light-exposure. The first strip portion and the second strip portion have an overlapping portion that is double exposed. The method further includes developing the photo resist to remove the first strip portion and the second strip portion, etching a dielectric layer underlying the photo resist to form a trench, and filling the trench with a conductive feature.

Abstract: A method includes performing a first light-exposure and a second a second light-exposure on a photo resist. The first light-exposure is performed using a first lithograph mask, which covers a first portion of the photo resist. The first portion of the photo resist has a first strip portion exposed in the first light-exposure. The second light-exposure is performed using a second lithograph mask, which covers a second portion of the photo resist. The second portion of the photo resist has a second strip portion exposed in the second light-exposure. The first strip portion and the second strip portion have an overlapping portion that is double exposed. The method further includes developing the photo resist to remove the first strip portion and the second strip portion, etching a dielectric layer underlying the photo resist to form a trench, and filling the trench with a conductive feature.

Abstract: A device includes a test pad on a chip. A first microbump has a first surface area that is less than a surface area of the test pad. A first conductive path couples the test pad to the first microbump. A second microbump has a second surface area that is less than the surface area of the test pad. A second conductive path couples the test pad to the second microbump.

Abstract: A device includes a substrate having a front surface and a back surface opposite the front surface. A capacitor is formed in the substrate and includes a first capacitor plate; a first insulation layer encircling the first capacitor plate; and a second capacitor plate encircling the first insulation layer. Each of the first capacitor plate, the first insulation layer, and the second capacitor plate extends from the front surface to the back surface of the substrate.

Abstract: An embodiment of the disclosure is a structure comprising an interposer. The interposer has a test structure extending along a periphery of the interposer, and at least a portion of the test structure is in a first redistribution element. The first redistribution element is on a first surface of a substrate of the interposer. The test structure is intermediate and electrically coupled to at least two probe pads.

Abstract: A method of manufacturing a package may include: providing a first device having a first redistribution layer (RDL) and an insulator layer disposed over the first RDL; and forming a first micro-bump line over the insulator layer of the first device. The first micro-bump line may extend laterally over a surface of the insulator layer facing away from the first RDL, and a first inductor of the package comprises the first RDL and the first micro-bump line.

Abstract: A semiconductor device, and a method of forming the device, are provided. The semiconductor device includes a first die having a first plurality of contact pads and a second die having a second plurality of contact pads. A substrate is bonded to a first contact pad of the first plurality of contact pads and a first contact pad of the second plurality of contact pads in a face-to-face orientation with the first die and the second die. A first through via extends through the substrate. Molding material is interposed between the first die, the second die and the substrate, the molding material extending along sidewalls of the first die, the second die, and the substrate. A second through via is positioned over a second contact pad of the first plurality of contact pads, the second through via extending through the molding material.

Abstract: Methods and apparatus for forming a semiconductor device package on an interposer using a micro-bump layer are disclosed. The micro-bump layer may comprise micro-bumps and micro-bump lines, where a micro-bump is used as a vertical connection between a die and the interposer, and a micro-bump line is used as a horizontal connection for signal transmission between different dies above the interposer. The micro-bump lines may be formed at the same time as the formation of the micro-bumps with little or no additional cost.

Abstract: A package includes a semiconductor chip. The semiconductor chip includes a test pad, and a plurality of microbump pads, wherein each microbump pad of the plurality of microbump pads is electrically connected to the test pad. The package further includes a substrate; and a plurality of microbumps configured to electrically connect the semiconductor chip to the substrate, wherein each microbump of the plurality of microbumps is electrically connected to a corresponding microbump pad of the plurality of microbump pads. The package further includes a package substrate, wherein the package substrate comprises a bump pad, wherein an area of the bump pad is greater than a combined area of the test pad and the plurality of microbump pads. The package further includes a bump configured to electrically connect the substrate to the package substrate.