In one embodiment, a motherboard to be cut, includes: a motherboard body provided, on a surface thereof, with a cutting line comprising a special-shaped cutting line section, wherein, a plurality of positional marker groups are provided on a portion of the surface where the special-shaped cutting line section is provided; each positional marker group includes a first marker assembly and a second marker assembly provided at both sides of the special-shaped cutting line section; and, in the arrangement direction of the first marker assembly and the second marker assembly, size of the first marker assembly is not less than tolerance size of a side of the special-shaped cutting line section where the first marker assembly is in, and size of the second marker assembly is not less than tolerance size of a side of the special-shaped cutting line section where the second marker assembly is in.

The present disclosure provides a PCB board, a manufacturing method of a PCB board, and an electrical device, where the PCB board includes an insulating dielectric layer which is a glass substrate layer including a top surface and a bottom surface disposed oppositely; a conductive wiring layer which is disposed on a top surface of the insulating dielectric layer; and a top ink layer which is coated on the conductive wiring layer. According to the technical solution provided by the embodiment of the disclosure, the PCB board does not generate the phenomenon of deformation warping, and the conductive wiring layer is not easily peeled off from the insulating medium layer, and the use performance of the PCB board is good.

An adhesion between a sealing resin layer and a shield film is improved by a mesh sheet disposed on an opposite surface of the sealing resin layer. A radio frequency module includes a wiring board, a component mounted on an upper surface of the wiring board, a sealing resin layer that covers the component, a mesh sheet disposed on an upper surface of the sealing resin layer, and a shield film provided to cover the upper surface and side surfaces of the sealing resin layer, and the mesh sheet. The mesh sheet and the sealing resin layer, as well as the mesh sheet and the shield film are firmly in adhesion with one another. Thus, the adhesion between the sealing resin layer and the shield film can be improved.

Described herein are capacitive devices and methods for producing same using printing methods such as flexography, gravure, offset, lithography, etc. The capacitive devices are formed from printing conductive inks, non-conductive inks, masking ink layers, graphic artwork layers, and overprint layers on a substrate. Interaction between a conductive ink layer of the capacitive device with a touch screen device of a computer, tablet, smart phone, etc. causes a capacitive effect that allows information coded in capacitive device to be read, leading to an activity such as the download of content to the device having the touch screen.

An electronic circuit module includes a circuit board, electronic components, a burying layer, and a conductive film. The circuit board includes a first principal surface on which first electrodes are provided, a second principal surface on which second electrodes including grounding electrodes are provided, and a side surface connecting the first principal surface and the second principal surface. The electronic components are connected to the first electrodes. The burying layer is provided on the first principal surface of the circuit board with the electronic components buried therein. The conductive film is connected to the grounding electrodes. The outer surface of the burying layer includes markings with protruding shapes with respect to the outer surface of the burying layer. The conductive film covers the outer surface of the burying layer.

A monochrome image forming apparatus includes an image forming unit that forms a black image, a motor that drives the image forming unit, a control circuit that controls the motor, a first connector to which the motor is connected via a control line, a second connector to which a control target is not connected, and a substrate on which the control circuit, the first connector, and the second connector are arranged. A predetermined mark is formed on the substrate through silk screen printing. A distance between the predetermined mark and the second connector is shorter than a distance between the predetermined mark and the first connector. If the substrate is disposed in a multi-color image forming apparatus configured to form a color image, a control target for the multi-color image forming apparatus is connected to the second connector.

Methods and devices that identify a silkscreen data file associated with a physical printed circuit board and use an image of the physical printed circuit board to display a virtual silkscreen over the image of the physical printed circuit board.

A printed circuit board having a substrate layer, at least one electrically conductive trace disposed on the substrate layer, and a solder mask layer disposed over the substrate layer and the electrically conductive trace, wherein the solder mask later includes a void region over at least a portion of the electrically conductive trace. Also, a method of optimizing printed circuit board designing including selecting printed circuit board data comprising at least a solder mask layer area, varying the solder mask layer area, determining an insertion loss value for each varied solder mask layer area, comparing the insertion loss values for each varied solder mask layer area, and selecting a solder mask layer area based on the comparing.

Provided are a liner and a display device including the same. The liner includes a first liner including a first shield can protection portion, a first grip portion, and a connection portion coupling the first shield can protection portion to the first grip portion, a second liner including a second shield can protection portion and a second grip portion, and a perforated line formed along a boundary between the first liner and the second shield can protection portion.

A high-frequency device includes: a circuit substrate including dielectric layers that are stacked, wiring patterns located on at least one of the dielectric layers, and a passive element formed of at least one of the wiring patterns, the circuit substrate having a first surface that is a surface of an outermost dielectric layer in a stacking direction of the dielectric layers; a terminal for connecting the high-frequency device to an external circuit, the terminal being located on the first surface and electrically connected to the passive element through a first path in the circuit substrate; and an acoustic wave element located on the first surface and electrically connected to the passive element through a second path in the circuit substrate.