Abstract: An organic light emitting display apparatus and method of manufacturing the same to improve an image quality of the organic light emitting display apparatus. The organic light emitting display apparatus includes: a first electrode formed on a substrate; an intermediate layer disposed on the first electrode, the intermediate layer having an organic emission layer; and a second electrode formed on the intermediate layer, wherein the first electrode includes an etching unit facing the intermediate layer.

Abstract: A microelectronic structure comprising a microelectronic package that includes at least one microelectronic device attached to a microelectronic interposer, wherein the microelectronic package is mounted to a microelectronic substrate, such that the microelectronic device is disposed between and in electrical communication with both the microelectronic interposer and the microelectronic substrate.

Abstract: A memory cell array and a resistive variable memory device including the memory cell array are provided. The memory cell array includes a memory group. The memory cell array includes a pair of word lines, an inter-pattern insulating layer interposed between the pair of word lines, and a plurality of active pillars, each having one side contacted with the inter-pattern insulating layer and other sides surrounded by the word line.

Abstract: Embodiments generally include a method of forming a nonvolatile memory device that contains a resistive switching memory element that has an improved device switching capacity by using multiple layers of variable resistance layers. In one embodiment, the resistive switching element comprises at least three layers of variable resistance materials to increase the number of logic states. Each variable resistance layer may have an associated high resistance state and an associated low resistance state. As the resistance of each variable resistance layer determines the digital data bit that is stored, the multiple variable resistance layers per memory element allows for additional data storage without the need to further increase the density of nonvolatile memory devices.

Abstract: A semiconductor device is made by mounting a plurality of semiconductor die to a substrate, depositing an encapsulant over the substrate and semiconductor die, forming a shielding layer over the semiconductor die, creating a channel in a peripheral region around the semiconductor die through the shielding layer, encapsulant and substrate at least to a ground plane within the substrate, depositing a conductive material in the channel, and removing a portion of the conductive material in the channel to create conductive vias in the channel which provide electrical connection between the shielding layer and ground plane. An interconnect structure is formed on the substrate and are electrically connected to the ground plane. Solder bumps are formed on a backside of the substrate opposite the semiconductor die. The shielding layer is connected to a ground point through the conductive via, ground plane, interconnect structure, and solder bumps of the substrate.

Abstract: A device is disclosed which includes a flexible material including at least one conductive wiring trace, a first die including at least an integrated circuit, the first die being positioned above a portion of the flexible material, and an encapsulant material that covers the first die and at least a portion of the flexible material. A method is disclosed which includes positioning a first die above a portion of a flexible material, the first die including an integrated circuit and the flexible material including at least one conductive wiring trace, and forming an encapsulant material that covers the first die and at least a portion of the flexible material, wherein at least a portion of the flexible material extends beyond the encapsulant material.

Abstract: A DC-DC boost converter in multi-die package is proposed having an output Schottky diode and a low-side vertical MOSFET controlled by a power regulating controller (PRC). The multi-die package includes a single die pad with the Schottky diode placed there on side by side with the vertical MOSFET. The PRC die is attached atop the single die pad via an insulating die bond. Alternatively, the single die pad is grounded. The vertical MOSFET is a top drain vertical N-channel FET, the substrate of Schottky diode die is its anode. The Schottky diode and the vertical MOSFET are stacked atop the single die pad. The PRC is attached atop the single die pad via a standard conductive die bond. The Schottky diode die can be supplied in a flip-chip configuration with cathode being its substrate. Alternatively, the Schottky diode is supplied with anode being its substrate without the flip-chip configuration.

Abstract: Microelectronic packages are fabricated by stacking integrated circuits upon one another. Each integrated circuit includes a semiconductor layer having microelectronic devices and a wiring layer on the semiconductor layer having wiring that selectively interconnects the microelectronic devices. After stacking, a via is formed that extends through at least two of the integrated circuits that are stacked upon one another. Then, the via is filled with conductive material that selectively electrically contacts the wiring. Related microelectronic packages arc also described.

Abstract: A chip package structure including a substrate, a first chip and a second chip is provided. The first contacts and the second contacts of the substrate are respectively arranged to reside on a first side region and a second side region of the substrate. The first chip disposed on the substrate and has a plurality of first bonding pads arranged to reside on a first wire-bonding region of the first chip adjacent to the first contacts and are electrically connected to the first contacts via a plurality of first wires. The second chip is disposed on the first chip away from the symmetrical center of the first chip. The second chip has a plurality of second bonding pads arranged to reside on a second wire-bonding region of the second chip adjacent to the second contacts and are electrically connected to the second contacts via a plurality of second wires.

Abstract: A multi-ported CAM cell in which the negative effects of increased travel distance have been substantially reduced is provided. The multi-ported CAM cell is achieved in the present invention by utilizing three-dimensional integration in which multiple active circuit layers are vertically stack and vertically aligned interconnects are employed to connect a device from one of the stacked layers to another device in another stack layer. By vertically stacking multiple active circuit layers with vertically aligned interconnects, each compare port of the multi-port CAM can be implemented on a separate layer above or below the primary data storage cell. This allows the multi-port CAM structure to be implemented within the same area footprint as a standard Random Access Memory (RAM) cell, minimizing data access and match compare delays. Each compare match line and data bit line has the length associated with a simple two-dimensional Static Random Access Memory (SRAM) cell array.

Abstract: A DC-DC boost converter in multi-die package is proposed having an output Schottky diode and a low-side vertical MOSFET controlled by a power regulating controller (PRC). The multi-die package includes a single die pad with the Schottky diode placed there on side by side with the vertical MOSFET. The PRC die is attached atop the single die pad via an insulating die bond. Alternatively, the single die pad is grounded. The vertical MOSFET is a top drain vertical N-channel FET, the substrate of Schottky diode die is its anode. The Schottky diode and the vertical MOSFET are stacked atop the single die pad. The PRC is attached atop the single die pad via a standard conductive die bond. The Schottky diode die can be supplied in a flip-chip configuration with cathode being its substrate. Alternatively, the Schottky diode is supplied with anode being its substrate without the flip-chip configuration.