A method of manufacturing a cover window for a display device includes: providing a glass substrate having a bendable area and a flat area; modifying the bendable area by irradiating the glass substrate with a beam; and etching the bendable area to have a thinner thickness than the flat area. The bendable area may have a faster etch rate than the flat area due to the modifying of the bendable area.

Configurable smart object systems with methods of making modules and contactors are provided. Example systems implement machine learning based on neural networks that draw low power for use in smart phones, watches, drones, automobiles, and medical devices. Example assemblies can be configured from pluggable, interchangeable modules that have compatible ports for interconnecting and integrating functionally dissimilar sensor systems. An example method includes mounting an element of a configurable machine learning assembly on a substrate, creating at least one fold in the substrate, folding the substrate at the fold into a housing of a module of the configurable machine learning assembly, and adding a molding material to the housing to at least partially fill the module of the configurable machine learning assembly. The example module construction may also form contactors on folded edges of the module for making physical and electrical contact with other modules of the smart object machine learning assembly.

A resin multilayer board includes an insulating substrate including a first main surface and mounting electrodes only on the first main surface. The insulating substrate includes first and second resin layers that are laminated. The Young's modulus of the second resin layers is higher than that of the first resin layers. The first and second resin layers are arranged in a distributed manner along a lamination direction of the first and second resin layers. The insulating substrate includes a first and second portions that are two equally divided portions of the insulating substrate in the lamination direction and are respectively positioned closer to the first main surface and farther from the first main surface, and a volume ratio of the second resin layers in the first portion is higher than a volume ratio of the second resin layers in the second portion.

A rigid flex circuit board is provided, including a flexible circuit board, which includes a core layer, first and second cover layers, first and second bonding layers, first and second dielectric layers, and first and second superposition layers. The core layer includes first and second core circuit layers. The first and second cover layers cover a portion of the first and second core circuit layers. The first and second bonding layers cover a portion of the first and second cover layers. The first and second dielectric layers cover a portion of the first and second core circuit layers and the first and second cover layers. The first superposition layer is disposed on the first bonding layer and the first dielectric layer, and the second superposition layer is disposed on the second bonding layer and the second dielectric layer.

A semi-flexible component carrier includes a stack having at least one electrically conductive layer structure and at least one electrically insulating layer structure The layer structures are stacked on top of each other in a stacking direction s. A recess extends from a first main surface of the stack into the stack and extends only partially into one of the at least one electrically insulating layer structure so that an electrically insulating layer structure having a stepped portion is formed. The stepped portion provides a flexible region of the stack with respect to a rigid region of the stack.

The present disclosure relates to a printed circuit board and a module including the same. The printed circuit board includes an insulating body, a wiring pattern embedded in the insulating body, and a first conductor pattern disposed on the insulating body and overlapping at least a portion of the wiring pattern in a first direction. First conductive vias each penetrate a portion of the insulating body and are respectively disposed on opposite sides of the wiring pattern, in a second direction orthogonal to the first direction, to surround at least a portion of the wiring pattern. Each first conductive via has a first surface connected to the first conductor pattern, and a second surface, opposite to the first surface, connected to the insulating body.

An extensible flexible printed circuit board sets one or a plurality of flexible printed circuit boards each including a plurality of conductive layers and an insulting layer as a base circuit board, and includes: component mounting partners which are provided at least at parts of the base circuit board, and capable of mounting electronic components an extensible conductive part which is provided at least at a part of the base circuit board includes a plurality of joint parts each intersecting a center line in an extension/contraction direction and a plurality of curved parts each continuing from an end part of each joint part and curve, and exhibits extensibility by the curved parts curving to open or close; and a covering member whose material is a flexibly deformable elastomer, and which covers the component mounting parts and the extensible conductive part.

Provided is a printed circuit board, including: a support substrate including a first region in which light emitting elements are mount, a second region extending from the first region, and a bending portion between the first region and the second region, an insulating substrate on the support substrate, wiring portions on the insulating substrate, and a protective layer on the wiring portions.

A mobile device and a method of manufacturing a mobile device are disclosed. An aspect of the present invention provides a mobile device, which includes: a multi-layer circuit board including a plurality of circuit pattern layers and a plurality of dielectric layers and having a cavity formed on a lateral surface thereof toward an inside thereof; an electrode pad laminated in the cavity and configured to be electrically connected with the circuit pattern layers; and a conductive switch formed on an external peripheral portion of the cavity of the multi-layer circuit board in such a way that the conductive switch is separated from the electrode pad and is contactable with the electrode pad by an external force.

An electronic circuit includes plural individual electronic circuits arranged, in which each of the plural individual electronic circuits has a first conductor column that is connected to a ground of a first layer which is any one of plural conductor layers sequentially stacked in a separated state and extends in a stacking direction, a conductor line that is connected to the conductor column to extend in a band shape in a second layer different from the first layer which is any one of the plural conductor layers, and of which an end portion separated from the conductor column is an open end, and a second conductor column that is connected to the conductor line, is not connected to the ground, and extends in the stacking direction, and each of a first individual electronic circuit and a second individual electronic circuit adjacent to each other among the plural individual electronic circuits has at least a pair of the second conductor columns, which are formed at adjacent positions without interposing any one of the conductor lines of the first individual electronic circuit and the second individual electronic circuit between the pair of the second conductor columns.