A method of manufacturing a component carrier includes forming a poorly adhesive structure on at least one layer structure, thereafter removing part of the poorly adhesive structure to thereby define a lateral limit of the poorly adhesive structure, thereafter attaching at least one further layer structure to the at least one layer structure and to the poorly adhesive structure, and forming a cavity by removing material of the at least one further layer structure above the poorly adhesive structure.

Laminate structures and configurations of fiducials for laminates structures for electronic devices are disclosed. Fiducials are formed in laminate structures to provide increased visibility and contrast, thereby improving detection of the fiducials with optical detection equipment of automated machines commonly used in the electronics industry. Fiducials are disclosed that are defined by openings in laminate structures that extend to depths within the laminate structures to provide sufficient contrast. Openings for fiducials may be arranged to extend through multiple metal layers and dielectric layers of the laminate structures. The fiducials may be formed by laser drilling or other subtractive processing techniques. Fiducials as disclosed herein may be coated with additional layers or coatings, such as a metal coating that includes an electromagnetic shield for electronic devices, and the fiducials are configured with sufficient visibility and contrast to remain detectable through the additional layers or coatings.

An anisotropic conductive film, capable of connecting a terminal formed on a substrate having a wavy surface such as a ceramic module substrate with conduction characteristics stably maintained, includes an insulating adhesive layer, and conductive particles regularly arranged in the insulating adhesive layer as viewed in a plan view. The conductive particle diameter is 10 μm or more, and the thickness of the film is 1 or more times and 3.5 or less times the conductive particle diameter. The variation range of the conductive particles in the film thickness direction is less than 10% of the conductive particle diameter.

A method for manufacturing a multilayer wiring substrate includes forming a resist layer having mask pattern, forming a conductor layer having conductor pattern using the resist layer, removing the resist layer, forming an insulating layer on the conductor layer such that the insulating layer is laminated on the conductor layer, forming a subsequent resist layer having mask pattern such that the subsequent resist layer is formed on the insulating layer, and forming a subsequent conductor layer having conductor pattern using the subsequent resist layer. The forming of the resist layer includes conducting first correction in which formation position of entire mask pattern of the resist layer is corrected with respect to reference position, and conducting second correction in which shape of the mask pattern of the resist layer is corrected with respect to reference shape, and the forming of the subsequent resist layer does not include conducting the second correction.

The present invention relates to an electronic module. In particular, to an electronic module which includes one or more components embedded in an installation base. The electronic module can be a module like a circuit board, which includes several components, which are connected to each other electrically, through conducting structures manufactured in the module. The components can be passive components, microcircuits, semiconductor components, or other similar components. Components that are typically connected to a circuit board form one group of components. Another important group of components are components that are typically packaged for connection to a circuit board. The electronic modules to which the invention relates can, of course, also include other types of components.

The present disclosure enables a cost reduction for a circuit assembly including electronic components. A circuit assembly includes: an electronic component; a conductive plate to which the electronic component is connected; and a holding member that holds the conductive plate. The conductive plate includes a mounting portion on which the electronic component is mounted, and a fiducial mark for positioning and mounting the electronic component. The fiducial mark is constituted by a hole formed in the conductive plate.

The disclosure provides a bonding method, the bonding method includes: bonding first areas of a plurality of flexible printed circuit boards on a substrate, the plurality of flexible printed circuit boards being sequentially arranged along a direction parallel to a first side of the substrate, and a second area of each of the flexible printed circuit boards exceeds the first side; cutting at least one of the flexible printed circuit boards to enable second sides of all the flexible printed circuit boards to be flush and parallel to the first side, wherein each of the second sides is a side of the second area away from the first area; and bonding second areas of the flexible printed circuit boards with a connection circuit board.

An anisotropic conductive film, capable of connecting a terminal formed on a substrate having a wavy surface such as a ceramic module substrate with conduction characteristics stably maintained, includes an insulating adhesive layer, and conductive particles regularly arranged in the insulating adhesive layer as viewed in a plan view. The conductive particle diameter is 10 μm or more, and the thickness of the film is 1 or more times and 3.5 or less times the conductive particle diameter. The variation range of the conductive particles in the film thickness direction is less than 10% of the conductive particle diameter.

A circuit board includes an interconnect and an insulating layer that covers the interconnect. The interconnect includes a first interconnect that is formed to serve as a recognition mark of which planar shape is a predetermined shape. The insulating layer has a through-hole of which planar shape is variant and that penetrates the insulating layer in a thickness direction of the insulating layer such that an entire upper surface of the first interconnect is exposed. The through-hole includes a first through-hole of which planar shape is a predetermined shape and that penetrates the insulating layer in the thickness direction such that the entire upper surface of the first interconnect is exposed and a second through-hole that serves as part of an inner wall surface of the first through-hole and that penetrates the insulating layer in the thickness direction.

According to one embodiment, a display device includes a display panel including a first substrate, and a wiring board mounted on a mounting portion of the first substrate. The display panel includes a first terminal and a second terminal located in the mounting portion, a first alignment mark located in the mounting portion and located between the first terminal and the second terminal, a first wiring line connected to the first terminal, and a second wiring line connected to the second terminal. The wiring board includes a first connection wiring line connected to the first terminal, a second connection wiring line connected to the second terminal, and a second alignment mark located between the first connection wiring line and the second connection wiring line.