A flexible circuit board includes a flexible light-permeable carrier, a circuit layer, a mark and a stiffener. The circuit layer and the mark are located on a top surface of the flexible light-permeable carrier. A predetermined area and a stiffener mounting area corresponding to each other are defined on the top surface and a bottom surface of the flexible light-permeable carrier, respectively. The mark is opaque to create a shadow mark having a longitudinal reference side and a lateral reference side on the bottom surface. The stiffener is adhered to the stiffener mounting area defined on the bottom surface by aligning with the longitudinal reference side and the lateral reference side of the shadow mark.

A fiducial mark allocation method including: allocating at least two fiducial marks out of three or more fiducial marks provided on a board to a component to be used for calculating a correction amount of a mounting position of the component on the board; determining whether the mounting position of the component is within a range defined by the fiducial marks in an X direction, a Y direction, or both the X direction and the Y direction, wherein the allocating of the at least two fiducial marks is performed based on whether the mounting position of the component is within a range defined by the fiducial marks in the X direction, the Y direction, or both the X direction and the Y direction.

The display device comprises a first base portion including display and non-display areas and a pad area, and a printed circuit film attached to the pad area of the first base portion, wherein pad electrodes on the first base portion and a first panel alignment mark on one side of the plurality of pad electrodes are disposed in the pad area, a first protective layer is on the pad electrodes, and a first open portion that exposes a portion of an upper surface of each pad electrode is defined in the protective layer, the printed circuit film includes a third base portion and lead electrodes on a lower surface of the third base portion and connected to the pad electrodes, and the first panel alignment mark includes a first panel alignment metal portion and a second open portion and surrounded by the first panel alignment metal portion on a plane.

A wiring circuit board includes an alignment mark layer. The alignment mark layer includes a first alignment mark and a second alignment mark. The condition A or the condition B is satisfied. Condition A: The first alignment mark has a first portion (a first starting point portion or a first center of gravity portion). The second alignment mark has a second portion (a second starting point portion or a second center of gravity portion). Condition B: The first alignment mark has the first portion, and the second alignment mark does not have the second portion, or the first alignment mark does not have the first portion, and the second alignment mark does not have the second portion.

A bonding pad structure includes a substrate, a flexible printed circuit board, and a plurality of bonding pins. The bonding pins include at least one central bonding pin and at least two first bonding pins. The at least one central bonding pin is located at a center of bonding pins. The at least two first bonding pins are located farthest away from the at least one central bonding pin and have mirror symmetry with respect to the at least one central bonding pin. The at least one central bonding pin includes a first end and a second end. A first width A of the first end and a second width B of the second end satisfy 0<A/B≤1.

A tilt angle θ is formed between one of the at least two first bonding pins and one side of the substrate and satisfies 0<θ≤90.

A device for introducing patterns by radiating a wound continuous substrate. The device provides patterning during continuous roll-to-roll movement without material slippage and with minimal distortion by providing a dancer roll between a processing drum and an unwinder roll on one side, and a winder roll on the other side, for tautly guiding the continuous substrate along a contact surface of at least half of the circumference of the processing drum in order to drive the continuous substrate without slippage. The dancer rolls are adapted to tautly guide the advancing substrate web and returning substrate web with a constant force, and an equilibrium is adjustable between a defined counterforce and the constant action of force on the dancer roll by a stabilization device, and is maintained constant by a controller based on measured deflections of the dancer roll by controlling the rotational speed of the unwinder and winder rolls.

A display device includes a display unit including transistors disposed in a display area and signal lines arranged in a non-display area located along an edge of the display area, at least one of the signal lines being electrically connected to the transistors; and an input sensing unit disposed over the display unit and including sensing electrodes disposed on the display area, sensing lines arranged on the non-display area, and a first dummy pattern disposed on the non-display area and spaced apart from the sensing electrodes as compared with the sensing line, wherein the first dummy pattern overlaps a first signal line of the signal lines, the first signal line being spaced farthest from the display area, a planar shape of an overlap pattern formed by overlapping the first dummy pattern and the first signal line coincides with a planar shape of an alignment mark.

A wiring circuit board includes an insulating layer, a wire embedded in the insulating layer, and an alignment mark electrically independent from the wire and disposed in the insulating layer so as to allow a one-side surface in a thickness direction of the alignment mark to be exposed from the insulating layer. A peripheral portion of the alignment mark consists of only the insulating layer and has a thickness of 30 μm or less.

Systems and methods for bonding an electronic component to substrate with a rough surface. The method comprising: disposing an insulating adhesive on the substrate; applying heat and pressure to the insulating adhesive to cause the adhesive to flow into at least one opening formed in the substrate; curing the insulating adhesive to form a pad that is at least partially embedded in the substrate and comprises a planar smooth surface that is exposed; disposing at least one trace on the planar smooth surface of the pad; depositing an anisotropic conductive material on the pad so as to at least cover the at least one trace; placing the electronic component on the pad so that an electrical coupling is formed between the electronic component and the at least one trace; and bonding the electronic component to the substrate by curing the anisotropic conductive material.

A method of inspecting a printed wiring board includes preparing a printed wiring board having product and inspection regions such that the board has inner-layer lands in the regions, forming vias on the inner-layer lands in the regions, forming outer peripheral part(s) in the wiring board such that the outer peripheral part(s) expose outer peripheral portion(s) of the inner-layer land in the inspection region, determining a center coordinate of the inner-layer land in the inspection region based on a position of the outer peripheral part(s), determining a center coordinate of the via(s) in the inspection region based on a shape of the via(s) in the inspection region, determining a misalignment amount based on a distance between the center coordinate of the inner-layer land and the center coordinate of the via(s) in the inspection region, and determining alignment accuracy between the via and the inner-layer land based on the misalignment amount.