Abstract: An imaging device includes a first substrate including a pixel array and a first multilayer wiring layer. The first multilayer wiring layer includes a first wiring that receives electrical signals based on electric charge generated by at least one photoelectric conversion unit, and a plurality of second wirings. The imaging device includes a second substrate including a second multilayer wiring layer and a logic circuit that processes the electrical signals. The second multilayer wiring layer includes a third wiring bonded to the first wiring, and a plurality of fourth wirings. At least one of the plurality of fourth wirings being bonded to at least one of the plurality of second wirings. The second multilayer wiring layer includes at least one fifth wiring that is connected to the plurality of fourth wirings and that receives a power supply signal.

Abstract: A semiconductor device includes a substrate, one or more transistors, a metal layer, one or more buried power rails, and at least one wall-via structure. The transistors and the metal layer are manufactured above a top surface of the substrate. The buried power rails are in one or more corresponding trenches in the substrate below the top surface of the substrate. At least one wall-via structure extends between the first buried power rail and the metal layer and electrically connects the first buried power rail to the metal layer. The wall-via structure includes a plurality of intermediate metal layers sandwiched between the first buried power rail and the metal layer. Alternatively, the wall-via structure includes a length that is greater than or equal to four times a basic length unit for components in layers between the first buried power rail and the metal layer for the semiconductor device.

Abstract: A semiconductor device includes an integrated circuit die having bond pads and a bond wires. The bond wires are connected to respective ones of the bond pads by a ball bond. An area of contact between the ball bond and the bond pad has a predetermined shape that is non-circular and includes at least one axis of symmetry. A ratio of the ball bond length to the ball bond width may be equal to a ratio of the bond pad length to the bond pad width.

Abstract: An electronic device includes: a support member that has a metallic placement surface joined to the conductive bonding layer, and a metallic sealing surface provided on an outer side of the placement surface in an in-plane direction of the placement surface to adjoin the placement surface and to surround the placement surface; and a resin member, which is a synthetic resin molded article, joined to the sealing surface and covering the electronic component. The sealing surface includes a rough surface having a plurality of laser irradiation marks having a substantially circular shape. The rough surface includes a first region and a second region. The second region has a higher density of the laser irradiation marks in the in-plane direction than the first region.

Abstract: Methods of forming transistors include providing a substrate material, forming a recess to a first depth in the substrate material, the recess corresponding to a gate region and extending in a channel length direction and a channel width direction that is perpendicular to the channel length direction, forming a trench structure in the substrate material by deepening the recess to a second depth using an isotropic process, forming an isolation layer on the substrate material, forming a gate portion of the isolation layer on the substrate material such that the gate portion of the isolation layer extends into the trench structure, and forming a gate on the isolation layer such that the gate extends into the trench structure.

Abstract: This disclosure is related to arranging micro devices in the donor substrate by either patterning or population so that there is no interfering with non-receiving pads and the non-interfering area in the donor substrate is maximized. This enables the transfer of micro devices to a receiver substrate with fewer steps.

Abstract: A semiconductor device with favorable electrical characteristics is provided. A highly reliable semiconductor device is provided. The semiconductor device includes a semiconductor layer, a first insulating layer, a second insulating layer, a metal oxide layer, and a conductive layer; the first insulating layer, the metal oxide layer, and the conductive layer are stacked in this order over the semiconductor layer; an end portion of the first insulating layer is located inward from an end portion of the semiconductor layer; an end portion of the metal oxide layer is located inward from the end portion of the first insulating layer; and an end portion of the conductive layer is located inward from the end portion of the metal oxide layer. The second insulating layer is preferably provided to cover the semiconductor layer, the first insulating layer, the metal oxide layer, and the conductive layer.

Abstract: There is provided a imaging device including: an N-type region formed for each pixel and configured to perform photoelectric conversion; an inter-pixel light-shielding wall penetrating a semiconductor substrate in a depth direction and formed between N-type regions configured to perform the photoelectric conversion, the N-type regions each being formed for each of pixels adjacent to each other; a P-type layer formed between the N-type region configured to perform the photoelectric conversion and the inter-pixel light-shielding wall; and a P-type region adjacent to the P-type layer and formed between the N-type region and an interface on a side of a light incident surface of the semiconductor substrate.

Abstract: An integrated circuit includes a power supply terminal, a reference terminal, and a signal terminal. A first protection device is coupled between the signal terminal and the power supply terminal, the first protection device including a first MOS transistor. A second protection device is coupled between the signal terminal and the reference terminal, the second protection device including a second MOS transistor. Gates of the MOS transistors are directly or indirectly coupled to the reference terminal. Substrates of the MOS transistors are coupled to the reference terminal via a common resistor.

Abstract: Disclosed is a method for manufacturing array substrate, including steps of: providing a substrate, forming a plurality of active switches on the substrate; forming a color filter layer on the substrate; forming a spacer unit layer on the color filter layer; and forming an electrode layer on the color filter layer and the spacer unit layer, including forming a first electrode layer in a display region of the substrate, and forming a second electrode layer in a non-display region of the substrate; where the first electrode layer is a pixel electrode layer, the spacer unit layer includes a spacer unit, and the first electrode layer includes a first electrode region overlying the spacer unit, where a vertical projection of the spacer unit along a thickness direction of the substrate has an overlap portion with a vertical projection of the first electrode layer along the thickness direction of the substrate.

Abstract: A package for power electronics includes a power substrate, a number of power semiconductor die, and a Kelvin connection contact. Each one of the power semiconductor die are on the power substrate and include a first power switching pad, a second power switching pad, a control pad, a semiconductor structure, and a Kelvin connection pad. The semiconductor structure is between the first power switching pad, the second power switching pad, and the control pad, and is configured such that a resistance of a power switching path between the first power switching pad and the second power switching pad is based on a control signal provided at the control pad. The Kelvin connection pad is coupled to the power switching path. The Kelvin connection contact is coupled to the Kelvin connection pad of each one of the power semiconductor die via a Kelvin conductive trace on the power substrate.

Abstract: An image sensor including a plurality of pixels, each pixel including a photodetector coupled to a control circuit, the photodetector being formed inside and on top of a first semiconductor substrate, and the control circuit including at least one first MOS transistor formed inside and on top of a second semiconductor substrate arranged on the first substrate, the sensor being intended to be illuminated on the side of the surface of the first substrate opposite to the second substrate, the sensor further comprising a shield arranged between the first and second substrates and extending over substantially the entire surface of the sensor, said shield including at least one electrically-conductive layer.

Abstract: An integrated circuit includes first and second active regions extending in a first direction, a first gate line extending in a second direction substantially perpendicular to the first direction and crossing the first and second active regions, and a first contact jumper including a first conductive pattern intersecting the first gate line above the first active region and a second conductive pattern extending in the second direction above the first gate line and connected to the first conductive pattern.

Abstract: An image sensor may include a substrate, and a plurality of wavelength separation filters on the substrate and arranged along an in-plane direction of the substrate. The wavelength separation filters include a first wavelength separation filter configured to selectively transmit incident light in the first wavelength spectrum, and photoelectrically convert the incident light in at least one of the second wavelength spectrum or the third wavelength spectrum, a second wavelength separation filter configured to selectively transmit the incident light in the second wavelength spectrum and photoelectrically convert the incident light in at least one of the first wavelength spectrum or the third wavelength spectrum, and a third wavelength separation filter configured to selectively transmit the incident light in the third wavelength spectrum and photoelectrically convert the incident light in at least one of the first wavelength spectrum or the second wavelength spectrum.

Abstract: A power module apparatus includes a power module having a package configured to seal a perimeter of a semiconductor device, and a heat radiator bonded to one surface of the package; a cooling device having a coolant passage through which coolant water flows, in which the heat radiator is attached to an opening provided on a way of the coolant passage, wherein the heat radiator of the power module is attached to the opening of the cooling device so that a height (ha) and a height (hb) are substantially identical to each other. The power module in which the heat radiator is attached to the opening formed at the upper surface portion of the cooling device can also be efficiently cooled, and thereby it becomes possible to reduce degradation due to overheating.

Abstract: A method of using a processing oven may include disposing at least one substrate in a chamber of the oven and activating a lamp assembly disposed above them to increase their temperature to a first temperature. A chemical vapor may be admitted into the chamber above the at least one substrate and an inert gas may be admitted into the chamber below the at least one substrate. The temperature of the at least one substrate may then be increased to a second temperature higher than the first temperature and then cooled down.

Abstract: A microelectronic device and/or microelectronic device package having a warpage control structure. The warpage control structure may be positioned over an encapsulating material, wherein the encapsulating material is positioned between the warpage control structure and a die positioned over a substrate. The warpage control structure may have a first thickness over a first portion of the encapsulating material and a second thickness over a second portion of the encapsulating material. Methods of forming the microelectronic device are also disclosed herein.

Abstract: A semiconductor structure includes a semiconductor device, a plurality of through semiconductor vias (TSV), a first seal ring, and a second seal ring. The TSVs are in the semiconductor device. Each of the TSVs has a first surface and a second surface opposite to the first surface. The first seal ring is located in proximity to an edge of the semiconductor structure and is physically connected to the first surface of each of the TSVs. The second seal ring is physically connected to the second surface of each of the TSVs.

Abstract: A method of manufacturing a semiconductor structure forming a redistribution layer (RDL); forming a conductive pad over the RDL; performing a first electrical test through the conductive pad; bonding a first die over the RDL by a connector; disposing a first underfill material to surround the connector; performing a second electrical test through the conductive pad; disposing a second die over the first die and the conductive pad; and disposing a second underfill material to surround the second die, wherein the conductive pad is at least partially in contact with the second underfill material, and is protruded from the RDL during the first electrical test and the second electrical test.

Abstract: A system and method for connecting semiconductor dies is provided. An embodiment comprises connecting a first semiconductor die with a first width to a second semiconductor die with a larger second width and that is still connected to a semiconductor wafer. The first semiconductor die is encapsulated after it is connected, and the encapsulant and first semiconductor die are thinned to expose a through substrate via within the first semiconductor die. The second semiconductor die is singulated from the semiconductor wafer, and the combined first semiconductor die and second semiconductor die are then connected to another substrate.