The invention provides an array substrate and chip bonding method, the array substrate comprising: an active area, and a bonding area located around the active area, wherein the bonding area is provided with an input terminal group, a first output terminal group and a second output terminal a group; the first output terminal group is located at a side of the input terminal group away from the active area, and the second output terminal group is located between the first output terminal group and the input terminal group; when bonding chips, the first output terminal group or the second output terminal group is selected to cooperate with the input terminal group for chip bonding according to the chip type. By simultaneously providing the first and second output terminal groups, the bonding of the second type chip increases the distance between the chip and the edge of the array substrate.

Disclosed are a display device and a method of manufacturing a display device. The method of a display device according to an exemplary embodiment of the present disclosure includes: a first transferring step of transferring a plurality of LEDs disposed on a wafer onto a plurality of donors; and a second transferring step of transferring the plurality of LEDs transferred onto the plurality of donors onto a display panel, in which in the second transferring step, an area where one of the plurality of donors overlaps the display panel partially overlaps an area where the other one of the plurality of donors overlaps the display panel. Therefore, the plurality of LEDs having different wavelengths is uniformly transferred to reduce a boundary caused by the difference in wavelengths and improve color uniformity.

An electronic device includes a substrate, and the substrate may include one or more layers. The one or more layers may include a dielectric material and may include one or more electrical traces. The electronic device may include a layer of conductive material, and the layer of conductive material may define a void in the conductive material. The electronic device may include a fiducial mark, and the fiducial mark may include a filler material positioned in the void defined by the conductive material. The fiducial mark may be coupled to the layer of conductive material. The filler material may have a lower reflectivity in comparison to the conductive material, for instance to provide a contrast with the conductive material.

According to one embodiment, there is provided a substrate bonding apparatus including a first chucking stage, a second chucking stage, and an alignment unit. The first chucking stage is configured to chuck a first substrate. The second chucking stage is disposed facing the first chucking stage. The second chucking stage is configured to chuck a second substrate. The alignment unit is configured to be inserted between the first chucking stage and the second chucking stage. The alignment unit includes a base body, a first detection element, and a second detection element. The base body includes a first main face and a second main face opposite to the first main face. The first detection element is disposed on the first main face. The second detection element is disposed on the second main face.

A package includes a semiconductor carrier, a first die, a second die, a first encapsulant, a second encapsulant, a first through insulating via (TIV), and a second TIV. The semiconductor carrier has a contact via embedded therein. The contact via is electrically grounded. The first die is disposed over the semiconductor carrier. The second die is stacked on the first die. The first encapsulant laterally encapsulates the first die. The second encapsulant laterally encapsulates the second die. The first TIV is aside the first die. The first TIV penetrates through the first encapsulant and is electrically connected to the contact via. The second TIV is aside the second die. The second TIV penetrates through the second encapsulant and is electrically connected to the contact via and the first TIV.

An example embodiment may include a method for placing on a carrier substrate a semiconductor device. The method may include providing a semiconductor substrate comprising a rectangular shaped assist chip, which may include at least one semiconductor device surrounded by a metal-free border. The method may also include dicing the semiconductor substrate to singulate the rectangular shaped assist chip. The method may further include providing a carrier substrate having adhesive thereon. The method may additionally include transferring to and placing on the carrier substrate the rectangular shaped assist chip, thereby contacting the adhesive with the rectangular shaped assist chip at least at a location of the semiconductor device. The method may finally include singulating the semiconductor device, while remaining attached to the carrier substrate by the adhesive, by removing a part of rectangular shaped assist chip other than the semiconductor device.

A method of transferring micro devices includes: aligning a detachable transfer plate by an alignment assistive mechanism; picking up the micro devices and detaching the detachable transfer plate from the alignment assistive mechanism; placing the detachable transfer plate with the micro devices thereon into a transfer head stocker capable of storing multiple detachable transfer plates; moving the transfer head stocker to a place near an another alignment assistive mechanism; disassembling the detachable transfer plate with the micro devices thereon from the transfer head stocker; moving the detachable transfer plate with the micro devices thereon to be assembled to another alignment assistive mechanism above a receiving substrate to form a device transfer assembly; aligning the micro devices on the detachable transfer plate with the receiving substrate; and transferring the micro devices to the receiving substrate by the another alignment assistive mechanism through the detachable transfer plate.

A die placement and coupling apparatus may include a die bonding attachment. The die placement and coupling apparatus may include a compliant head unit that may be adapted to optionally couple with a semiconductor die. The compliant head unit may include a die attach surface that may include a layer of compliant material. The layer of compliant material may be coupled to the compliant head unit. The die attach surface may be adapted to mate with the semiconductor die when the semiconductor die is coupled with the compliant head unit. The layer of compliant material may be adapted to yield in response to an applied force. The die placement and coupling apparatus may include a vacuum port in communication with the die attach surface. The port may be adapted to have a vacuum applied to the port, and the vacuum temporarily holds the semiconductor die to the die attach surface.

Flexible devices including conductive traces with enhanced stretchability, and methods of making and using the same are provided. The circuit die is disposed on a flexible substrate. Electrically conductive traces are formed in channels on the flexible substrate to electrically contact with contact pads of the circuit die. A first polymer liquid flows in the channels to cover a free surface of the traces. The circuit die can also be surrounded by a curing product of a second polymer liquid.

A method of manufacturing a semiconductor package and a semiconductor package in which positional alignment between a wafer and a substrate until the wafer is mounted and packaged on the substrate is achieved accurately. A wafer is mounted on a package substrate by using first alignment marks and D-cuts as benchmarks, and then a mold resin layer is formed on the wafer in a state in which the first alignment mark is exposed. A part of the mold resin layer is removed by using the D-cuts exposed from the mold resin layer as benchmarks, so that the first alignment marks can be visually recognized. A second alignment marks are formed on the mold resin layer by using the first alignment marks as benchmarks. A Cu redistribution layer to be conducted to a pad portion is formed on a mold resin layer by using the second alignment marks as benchmarks.