Abstract: The present disclosure describes heat dissipating structures that can be formed either in functional or non-functional areas of three-dimensional system on integrated chip structures. In some embodiments, the heat dissipating structures maintain an average operating temperature of memory dies or chips below about 90° C. For example, a structure includes a stack with chip layers, where each chip layer includes one or more chips and an edge portion. The structure further includes a thermal interface material disposed on the edge portion of each chip layer, a thermal interface material layer disposed over a top chip layer of the stack, and a heat sink over the thermal interface material layer.

Abstract: The present disclosure provides a method and a system for determining the equivalence of the DRM data set and the DRC data set. The system retrieves a DRM data set and a DRC data set, and transforms the DRM data set and the DRC data set into a first data structure node and a second data structure node respectively. The system determines whether the first data structure node and the second data structure node are equivalent according to a data structure node comparison model.

Abstract: A three dimensional Integrated Circuit (IC) Power Grid (PG) may be provided. The three dimensional IC PG may comprise a first IC die, a second IC die, an interface, and a power distribution structure. The interface may be disposed between the first IC die and the second IC die. The power distribution structure may be connected to the interface. The power distribution structure may comprise at least one Through-Silicon Vias (TSV) and a ladder structure connected to at least one TSV.

Abstract: The present disclosure relates to a semiconductor module. The semiconductor module includes an excitable element located on a first side of a substrate. A first ground structure is disposed between the first side of the substrate and the excitable element. The first ground structure includes a conductive via extending through the substrate and an interconnect disposed over a topmost surface of the conductive via facing away from the substrate. A second ground structure is located on a second side of the substrate, opposing the first side, and electrically coupled to the first ground structure.

Abstract: The present disclosure relates to a semiconductor device and a manufacturing method, and more particularly to a semiconductor interposer device. The semiconductor interposer device includes a substrate and a first metallization layer formed on the substrate. A first dielectric layer is formed on the first metallization layer and a second metallization layer is formed on the substrate. A first conducting line is formed in the first metallization layer and second and third conducting lines are formed in the second metallization layer. A metal-insulator-metal (MIM) capacitor is formed in the first dielectric layer and over the first conducting line.

Abstract: A method of generating a layout diagram including a first level of metallization (M_1st level) including: identifying, in the layout diagram, a filler cell and a first functional cell substantially abutting the filler cell; the first functional cell including first and second side boundaries, first wiring patterns in the M_1st level, and representing corresponding first conductors in the first functional cell region; and first and second groups of cut patterns overlying corresponding portions of the first wiring patterns and being substantially aligned with the corresponding first and second side boundaries; adjusting one or more locations of corresponding one or more selected cut patterns of the second group thereby correspondingly elongating one or more selected ones of the first wiring patterns so as to be corresponding first elongated wiring patterns which extend across the second boundary of the first functional cell into the filler cell.

Abstract: An integrated circuit includes a first semiconductor wafer, a second semiconductor wafer, a first interconnect structure, an inductor, and a through substrate via. The first semiconductor wafer has a first device in a first side of the first semiconductor wafer. The second semiconductor wafer is over the first semiconductor wafer. The first interconnect structure is on a second side of the first semiconductor wafer opposite from the first side of the first semiconductor wafer. The inductor is below the first semiconductor wafer, and at least a portion of the inductor is within the first interconnect structure. The through substrate via extends through the first semiconductor wafer. The inductor is coupled to at least the first device by at least the through substrate via.

Abstract: A chip-scale sensor package structure includes a sensor chip, a first package body surrounding and connected to an outer lateral side of the sensor chip, a ring-shaped support disposed on a top side of the first package body, a light permeable member disposed on the ring-shaped support, and a redistribution layer (RDL) disposed on a bottom surface of the sensor chip and a bottom side of the first package body. The sensor chip includes a sensing region arranged on the top surface thereof, a plurality of internal contacts, and a plurality of conductive paths respectively connected to the internal contacts and electrically coupled to the sensing region. The sensing region is spaced apart from the ring-shaped support by a distance less than 300 ?m. A bottom surface of the RDL has a plurality of external contacts electrically coupled to the internal contacts.

Abstract: A sensor package structure includes a substrate, a sensor chip and a ring-shaped solder mask frame those are disposed on the substrate, a ring-shaped support disposed on a top side of the annular solder mask frame, and a light permeable member that is disposed on the ring-shaped support. The sensor chip is electrically coupled to the substrate. A top surface of the sensor chip has a sensing region, and the sensing region is spaced apart from an outer lateral side of the sensor chip by a distance less than 300 ?m. The ring-shaped solder mask frame surrounds and contacts the outer lateral side of the sensor chip. The light permeable member, the ring-shaped support, and the sensor chip jointly define an enclosed space.

Abstract: A method of manufacturing a semiconductor device includes forming a transistor layer with an M*1st layer that overlays the transistor layer with one or more first conductors that extend in a first direction. Forming an M*2nd layer that overlays the M*1st layer with one or more second conductors which extend in a second direction. Forming a first pin in the M*2nd layer representing an output pin of a cell region. Forming a long axis of the first pin substantially along a selected one of the one or more second conductors. Forming a majority of the total number of pins in the M*1st layer, the forming including: forming second, third, fourth and fifth pins in the M*1st layer representing corresponding input pins of the circuit; and forming long axes of the second to fifth pins substantially along corresponding ones of the one or more first conductors.

Abstract: A sensor package structure includes a substrate, a sensor chip disposed on and electrically coupled to the substrate, an opaque support (e.g., a ring-shaped solder mask) disposed on the sensor chip, and a light permeable layer disposed on the opaque support. The sensor chip includes a sensing region. The opaque support surrounds the sensing region, and inner lateral sides of the opaque support form a light-scattering loop wall. The light permeable layer, the light-scattering loop wall of the opaque support, and the sensor chip jointly define an enclosed space therein. When light passes through the light permeable layer and impinges onto the light-scattering loop wall at an incident angle, the light-scattering loop wall scatters the light into multiple rays at angles different from the incident angle.

Abstract: The present disclosure provides a method and a system for determining the equivalence of the DRM data set and the DRC data set. The system retrieves a DRM data set and a DRC data set, and transforms the DRM data set and the DRC data set into a first data structure node and a second data structure node respectively. The system determines whether the first data structure node and the second data structure node are equivalent according to a data structure node comparison model.

Abstract: A semiconductor device package includes a substrate, a first electronic component, a second electronic component, a package body and a shield. The substrate has a first surface and a second surface opposite to the first surface. The substrate defines a cavity from the second surface extending into the substrate. The first electronic component is disposed on the first surface of the substrate. The second electronic component is disposed within the cavity of the substrate. The package body is disposed on a portion of the first surface of the substrate and covers the first electronic component. The shield is disposed on external surfaces of the package body.

Abstract: An entangled inductor structure generates opposite polarity internal magnetic fields therein to substantially reduce, or cancel, external magnetic fields propagating outside of the entangled inductor structure. These reduced external magnetic fields propagating outside of the entangled inductor structure effectively reduce a keep out zone (KOZ) between the entangled inductor structure and other electrical, mechanical, and/or electro-mechanical components. This allows the entangled inductor structure to be situated closer to these other electrical, mechanical, and/or electro-mechanical components within the IC as compared to conventional inductors which generate larger external magnetic fields.

Abstract: The present disclosure describes heat dissipating structures that can be formed either in functional or non-functional areas of three-dimensional system on integrated chip structures. In some embodiments, the heat dissipating structures maintain an average operating temperature of memory dies or chips below about 90° C. For example, a structure includes a stack with chip layers, where each chip layer includes one or more chips and an edge portion. The structure further includes a thermal interface material disposed on the edge portion of each chip layer, a thermal interface material layer disposed over a top chip layer of the stack, and a heat sink over the thermal interface material layer.

Abstract: The present disclosure relates to a semiconductor device and a manufacturing method, and more particularly to a semiconductor interposer device. The semiconductor interposer device includes a substrate and a first metallization layer formed on the substrate. A first dielectric layer is formed on the first metallization layer and a second metallization layer is formed on the substrate. A first conducting line is formed in the first metallization layer and second and third conducting lines are formed in the second metallization layer. A metal-insulator-metal (MIM) capacitor is formed in the first dielectric layer and over the first conducting line.

Abstract: A three dimensional Integrated Circuit (IC) Power Grid (PG) may be provided. The three dimensional IC PG may comprise a first IC die, a second IC die, an interface, and a power distribution structure. The interface may be disposed between the first IC die and the second IC die. The power distribution structure may be connected to the interface. The power distribution structure may comprise at least one Through-Silicon Vias (TSV) and a ladder structure connected to at least one TSV.

Abstract: The present disclosure relates to an integrated antenna structure. The integrated antenna structure includes a radiator and a ground plane disposed between a semiconductor substrate and the radiator. A conductive structure is separated from the ground plane by the semiconductor substrate. The conductive structure is electrically coupled to the ground plane. The semiconductor substrate has a thickness of less than approximately 100 microns.

Abstract: An integrated circuit includes a first and second semiconductor wafer, a bonding layer, a first and second interconnect structure, an inductor, and a through substrate via. The first semiconductor wafer has a first device in a first side of the first semiconductor wafer. The second semiconductor wafer is over the first semiconductor wafer. The bonding layer is between the first and the second semiconductor wafer. The first interconnect structure is on a second side of the first semiconductor wafer. The inductor is below the first semiconductor wafer. At least a portion of the inductor is within the first interconnect structure. The second interconnect structure is on the first side of the first semiconductor wafer. The through substrate via extends through the first semiconductor wafer. The inductor is coupled to at least the first device by the second interconnect structure and the through substrate via.

Abstract: The present disclosure describes structures and methods for a via structure for three-dimensional integrated circuit (IC) packaging. The via structure includes a middle portion that extends through a planar structure and a first end and a second end each connected to the middle portion and on a different side of the planar structure. One or more of the first end and the second end includes one or more of a plurality of vias and a pseudo metal layer.