Integrated active-matrix multi-color light emitting pixel arrays based displays and methods of fabricating the integrated displays are provided. An example integrated device includes a backplane device and different color light emitting diodes (LEDs) devices arranged in different height planar layers on the backplane device. The backplane device includes at least one backplane having a number of pixel circuits. Each LED device includes an array of LEDs each operable to emit light with a particular color and conductively coupled to respective pixel circuits in the backplane to form active-matrix LED sub-pixels. The different color LED sub-pixels form an array of active-matrix multi-color display pixels. Plug vias can be arranged in different planar layers to conductively couple upper-level LEDs to respective pixel circuits in respective regions over the backplane device. The plug vias can extend from an upper planar layer into a lower planar layer to fix the two planar layers together.

Integrated active-matrix multi-color light emitting pixel arrays based displays and methods of fabricating the integrated displays are provided. An example integrated device includes a backplane device and different color light emitting diodes (LEDs) devices arranged in different height planar layers on the backplane device. The backplane device includes at least one backplane having a number of pixel circuits. Each LED device includes an array of LEDs each operable to emit light with a particular color and conductively coupled to respective pixel circuits in the backplane to form active-matrix LED sub-pixels. The different color LED sub-pixels form an array of active-matrix multi-color display pixels. Plug vias can be arranged in different planar layers to conductively couple upper-level LEDs to respective pixel circuits in respective regions over the backplane device. The plug vias can extend from an upper planar layer into a lower planar layer to fix the two planar layers together.

A wiring body disposed above a substrate including a conductor includes: a via electrode provided in a via hole formed in an insulating layer above the substrate and connected to the conductor through the via hole; and wiring provided above the substrate with the insulating layer interposed therebetween. The material or structure of a lower layer in the via electrode and the material or structure of a lower layer in the wiring are different.

Integrated active-matrix multi-color light emitting pixel arrays based displays and methods of fabricating the integrated displays are provided. An example integrated device includes a backplane device and different color light emitting diodes (LEDs) devices arranged in different height planar layers on the backplane device. The backplane device includes at least one backplane having a number of pixel circuits. Each LED device includes an array of LEDs each operable to emit light with a particular color and conductively coupled to respective pixel circuits in the backplane to form active-matrix LED sub-pixels. The different color LED sub-pixels form an array of active-matrix multi-color display pixels. Plug vias can be arranged in different planar layers to conductively couple upper-level LEDs to respective pixel circuits in respective regions over the backplane device. The plug vias can extend from an upper planar layer into a lower planar layer to fix the two planar layers together.

The present disclosure relates to a non-conductive film comprising an adhesive layer containing a low molecular weight epoxy resin; and a tacky layer containing a predetermined composition, and a method for manufacturing a semiconductor laminate using the non-conductive film.

A package carrier board includes a first circuit build-up structure, a patterned magnetic conductive metal layer, a plurality of first conductive pillar, a second insulating layer, and a second circuit build-up structure. The patterned magnetic conductive metal layer is disposed above the first circuit build-up structure, and the cross-sectional pattern of the patterned magnetic conductive metal layer is L-shaped and/or U-shaped. The first conductive pillars are disposed on the first circuit build-up structure and located outside of the patterned magnetic conductive metal layer. The second insulating layer covers the patterned magnetic conductive metal layer and the first conductive pillars. The second circuit build-up structure is disposed on the second insulating layer. The first circuit build-up structure, the first conductive pillars, the second insulating layer, and the second circuit build-up structure are combined to form an inductive circuit structure. Additionally, a manufacturing method for the package carrier board is also disclosed.

An interconnect substrate includes an interconnect layer, an insulating layer covering the interconnect layer, an electrode disposed on an upper surface of the interconnect layer and protruding from an upper surface of the insulating layer, and a groove formed in the upper surface of the insulating layer around the electrode, wherein the electrode includes a first portion whose side surface is covered with the insulating layer, a second portion whose entire side surface is located outside the insulating layer, the second portion being partially located inside the groove and partially protruding above the upper surface of the insulating layer, and a metal layer covering both an upper surface of the second portion and the entire side surface of the second portion.

HEMT having a drain field plate is provided. The drain field plate is formed in the area between the gate and drain of a HEMT. The drain field plate includes a metal pad that has a larger projection area than the drain pad. The drain field plate and semiconductor layer disposed beneath the drain field plate form a metal-semiconductor (M-S) Schottky structure. The capacitance of the M-S Schottky structure generates capacitance in the semiconductor area, which increases the breakdown voltage of the transistor components of the HEMT. A portion of the substrate under the active area may be removed to thereby increase the heat conductivity and reduce the junction temperature of the transistor components of the HEMT.

A package carrier includes a signal board, a power board and a connection layer. The signal board includes a plurality of first circuits. The power board includes a plurality of second circuits. A line width of each of the first circuits is less than a line width of each of the second circuits, and a first thickness of the signal board is less than a second thickness of the power board. The connection layer is disposed between the signal board and the power board, wherein the power board is electrically connected to the signal board through the connection layer.

Chip packages are described herein that includes chiplets embedded in a core of a substrate of the chip package, such as a package substrate or an interposer. In one example, the chiplet includes voltage regulation circuitry that is coupled through a substrate core embedded inductor to an integrated circuit (IC) die mounted to the substrate.