A display device includes a display panel including first and second signal pads respectively disposed at one side and the other side of a center axis extending in a first direction and first and second fixing pads spaced apart from each other with the first and second signal pads interposed therebetween, and a flexible film including connection pads overlapping the signal pads and first and second alignment pads groups spaced apart from each other with the connection pads interposed therebetween. The first alignment pad group includes n first alignment pads arranged in the first direction, the second alignment pad group includes n second alignment pads corresponding to the first alignment pads, and a distance between corresponding first and second alignment pads decreases as a distance thereof from a display area decreases.

The present invention relates to an improved system and method for manufacturing flexible circuit boards (FSBs) using optical alignment and various bonding systems. The invention provides an improved process to connect together the layers of rigid-flex, flexible, and printed circuit boards while maintaining alignment of the layers prior to and possibly after a lamination step. An optical alignment system is provided, a preferred arrangement is enabled as an automated pinless bonding system (PBS), for securely gripping, aligning, transferring, and clamping, bonding and moving a bonded FSB employing a multi-axis orientation. An alternative manual optical alignment and bonding system is provided.

The present disclosure relates to a machining station for machining platelike workpieces (1) by means of at least one tool, in particular a drilling station for machining at least one circuit board, as well as to a method for controlling or identifying a platelike workpiece (1). The machining station has at least one X-ray radiation source (3), at least one detector (4) and a table (2) that can be positioned between the X-ray radiation source (3) and the detector (4), on which the workpiece (1) to be machined can be fastened. The table (2) has a receiving plate (6) made out of a material permeable to X-rays (5), in particular a plastic. The receiving plate (6) has at least one suction port (11) for extracting air and a distribution grid, which is connected in terms of flow with the at least one suction port (11) and consists of several channels (10) unilaterally open in a support surface (9) with beveled and/or rounded edges (13) and/or of inclinedly running through openings (14).

A display device includes a display panel including a pixel part to display an image, and a pad part connected to the pixel part; a first flexible circuit film coupled to the pad part and including a first alignment mark; and a second flexible circuit film coupled to the pad part, overlapping the first flexible circuit film, and including a second alignment mark aligned with the first alignment mark. The first and second alignment marks are located in an area where the first flexible circuit film overlaps the second flexible circuit film.

An electronic device includes a plurality of sub-electronic modules arranged side by side. Each of the sub-electronic modules includes a housing having a top wall, a bottom wall, and a pair of side walls, and a light guide pipe mounted on one of the side walls. The light guide pipe has an incident end, an emergent end located at a front portion of the housing, and a main body located between the incident end and the emergent end and extending in a length direction of the housing. The incident ends of the light guide pipes located between at least a pair of adjacent housings are staggered by a predetermined distance in the length direction.

A display device may include a main flexible printed circuit including a first alignment mark and electrically connected to a first panel; and a touch flexible printed circuit including a second alignment mark and electrically connected to a second panel that is perpendicular to the first panel, wherein the main flexible printed circuit is electrically connected to the touch flexible printed circuit through a pad region, and the touch flexible printed circuit includes a first overcoat region disposed between the first alignment mark and the second alignment mark.

Disclosed herein is a system for drilling in a multilayer printed circuit board. The system includes a source of electromagnetic radiation configured to transmit a measurement pulse in open air to a workpiece, an anode, a resettable electric charge sensor (ECS), operably connected to the anode, and a control unit, configured to receive at least one value indicative of the quantity of at least part of charged molecules received at the anode and determine a second value indicative of the quantity of charged molecules received at the anode that were derivative of emitted electrons responsive to the measurement pulse.

A microelectronic device includes a die less than 300 microns thick, and an interface tile. Die attach leads on the interface tile are electrically coupled to die terminals on the die through interface bonds. The microelectronic device includes an interposer between the die and the interface tile. Lateral perimeters of the die, the interposer, and the interface tile are aligned with each other. The microelectronic device may be formed by forming the interface bonds and an interposer layer, while the die is part of a wafer and the interface tile is part of an interface lamina. Kerfs are formed through the interface lamina, through the interposer, and partway through the wafer, around a lateral perimeter of the die. Material is subsequently removed at a back surface of the die to the kerfs, so that a thickness of the die is less than 300 microns.

A method of compensating misalignment during manufacturing laminate-type component carriers is disclosed. The method includes detecting an image of a region of interest of a component carrier structure during manufacturing the component carriers based on the component carrier structure, identifying a structural feature in the image of the region of interest showing misalignment with respect to a target design, and at least partially compensating the identified misalignment of the structural feature by modifying the target design of at least one correlated structural feature to be manufactured subsequently, wherein the at least one correlated structural feature is correlated to said structural feature showing misalignment.

An electronic component is an electronic component including a first surface, wherein a marking formed by a collection of a plurality of dot-shaped recesses is formed in the first surface, an inner surface of each of the plurality of dot-shaped recesses is a curved surface, when viewed in a direction perpendicular to the first surface, an region internal to an outline of each of the plurality of dot-shaped recesses is entirely non-flat, the electric component comprises one or more second regions internal to an outline of the marking when viewed in the direction perpendicular to the first surface, each of the one or more second regions not belonging to any of the plurality of dot-shaped recesses, each of the one or more second regions being chamfered, each of the one or more second regions being non-flat, and each of the one or more second regions is convex.