A semiconductor assembly includes a first die and a second die. The semiconductor assembly also includes a film on die (FOD) layer configured to attach the first die to the second die. The FOD layer is disposed on a first surface of the first die. The FOD layer includes a first portion comprising a first die attach film (DAF) disposed on an inner region of the first surface. The FOD layer also includes a second portion that includes a second DAF disposed on a peripheral region of the first surface surrounding the inner region. The second DAF includes a different material than the first DAF.

A photolithography exposure of a photoresist coating on a semiconductor wafer uses an optical projection system to form a latent image. The photolithography exposure further uses a mask with a set of multiple pattern focus (MPF) marks. Each MPF mark of includes features having different critical dimension (CD) sizes. The latent image is developed to form a developed photoresist pattern. Dimension sizes are measured of features of the developed photoresist pattern corresponding to the features of the MPF marks having different CD sizes. A spatial focus map of the photolithography exposure is constructed based on the measured dimension sizes. To determine the focal distance at an MPF mark, ratios or differences may be determined between the measured dimension sizes corresponding to the features of the MPF marks having different CD sizes, and the focal distance at the location of the MFP mark constructed based on the determined ratios or differences.

Provided is a method of manufacturing a substrate including an alignment mark, including: forming the alignment mark and a recess portion on the substrate, the alignment mark not penetrating the substrate and including a bottom portion with a lower infrared transmittance than that of a first surface and a second surface of the substrate; and aligning the substrate by orthogonally arranging predetermined positions of the first surface and the second surface of the substrate in a horizontal direction and an infrared ray camera and by image-identifying the alignment mark formed on the substrate with transmitted light of infrared rays emitted from the infrared ray camera.

Disclosed is an organic light emitting display device including a dam structure disposed in a non-display area of a substrate and an alignment mark disposed outside the dam structure. The alignment mark is not covered by, and does not overlap with, the dam structure, because the alignment mark is disposed outside the dame structure. Thus, a scribing process may be performed smoothly.

The present disclosure relates to an embedded packaging module comprising a first semiconductor device, a first packaging layer and a first wiring layer, the first semiconductor device having a first and a second face, at least two positioning bulges and at least one bonding pad being provided on the first face of the first semiconductor device; the first packaging layer being formed on both the first face and a surface adjacent to the first face, the positioning bulges being positioned in the first packaging layer, at least one first via hole being provided in the first packaging layer, the bottom of the first via hole being positioned in the bonding pad and contacting with the bonding pad; the first wiring layer being positioned on the side of the first packaging layer away from the first semiconductor device and being electrically connected with the bonding pad through the first via hole.

A mark for overlay error measurement and overlay error measurement is provided. The mark includes a first pattern and a second pattern. The first pattern is disposed on a first surface of a substrate. The second pattern is disposed on a second surface of the substrate. The second surface of the substrate is opposite to the first surface of the substrate. The first pattern overlaps at least a portion of the second pattern, and the first pattern and the second pattern collaboratively define a first overlay error.

Panel level packaging (PLP) with high accuracy and high scalability is disclosed. The PLP includes dies bonded face down onto an alignment carrier configured with die bond regions. Pre-bond and post bond inspection are performed at the carrier level to ensure accurate bonding of the dies to the carrier.

A package structure includes a plurality of semiconductor die, an insulating encapsulant and a redistribution layer. Each of the plurality of semiconductor dies includes a semiconductor substrate, conductive pads disposed on the semiconductor substrate, conductive posts disposed on the conductive pads, and at least one alignment mark located on the semiconductor substrate. The insulating encapsulant is encapsulating the plurality of semiconductor dies. The redistribution layer is disposed on the insulating encapsulant and electrically connected to the plurality of semiconductor dies.

A semiconductor device includes a semiconductor substrate having a first surface and a second surface opposing each other, a plurality of semiconductor elements disposed on the first surface in a device region, an insulating protective layer, and a connection pad. The second surface is divided into a first region overlapping the device region, and a second region surrounding the first region. The insulating protective layer is disposed on the second surface of the semiconductor substrate, and includes an edge pattern positioned in the second region. The edge pattern includes a thinner portion having a thickness smaller than a thickness of a center portion of the insulating protective layer positioned in the first region and/or an open region exposing the second surface of the semiconductor substrate. The connection pad is disposed on the center portion of the insulating protective layer and is electrically connected to the semiconductor elements.

A method for aligning to a pattern on a wafer is disclosed. The method includes the steps of obtaining a first inline image from a first sample wafer, obtaining a first contour pattern of an alignment mark pattern from the first inline image, using the first contour pattern to generate a first synthetic image in black and white pixels, using the first synthetic image as a reference to recognize the alignment mark pattern on a tested wafer, and aligning to a tested pattern on the tested wafer according to a position of the alignment mark pattern on the tested wafer and a coordinate information.