A package comprises a body, and an electrically conductive pattern supported by said body. An interface portion is configured to receive a module to a removable attachment with the package. The electrically conductive pattern comprises, at least partly within said interface portion, a wireless coupling pattern that constitutes one half of a wireless coupling arrangement.

A method of making a fluid channel in a printhead structure includes positioning a printhead die on a carrier; compression molding the die into a molded printhead structure; compression molding a first segment of a fluid channel into the molded printhead structure simultaneously with compression molding the die; and materially ablating a second segment of the fluid channel to couple the channel with a fluid feed hole in the die.

Provided is a method for manufacturing a flexible film. The method for the manufacturing the flexible film includes providing a parent film on which a plurality of film areas are defined, each of which having a detection pattern formed thereon, applying a voltage to each of the film areas to detect whether a defect exists, removing the detection pattern from respective ones of the film areas on which the defect is detected, and cutting out others of the film areas on which the defect is not detected.

A component carrier includes a first level stack of first plural of electrically conductive layer structures and/or first electrically insulating layer structures; a first component aligned within a first through hole cut out in the first level stack such that one of an upper or a lower surface of the first component is substantially flush with an respective upper or a lower surface of the first level stack second electrically conductive layer structures and/or second electrically insulating layer structures attached onto the upper and the lower surface of the first level stack thereby covering the first component at the upper and the lower surface of the first component and pressed to form a second level stack. A second component is aligned within a second through hole cut out in the second level stack such that one of upper or a lower surface of the second component is substantially flush with an upper or a lower surface of the second level stack.

Methods, systems, devices, and products for constructing a downhole tool electronics module. Methods may include creating a circuit board by metallizing at least part of a first surface on a first side of a substrate to define at least one metallized area on the first surface, wherein the substrate comprises a ceramic material and includes: the first side, including at least (i) the first surface, and (ii) an elevated surface elevated from the first surface, and a second side opposite the first side; flattening at least partially the elevated surface to a predefined first flatness to create a mounting portion by removing material from the elevated surface; attaching an electronics component to the first surface; and mounting the circuit board on an electronics carrier by adhering at least part of the mounting portion to a mounting surface on the electronics carrier. Flattening at least partially the elevated surface to the predefined first flatness may be carried out by removing the material by areal grinding.

Embodiments of the invention include LED lighting systems and methods. For example, in some embodiments, an LED lighting system is included. The LED lighting system can include a flexible layered circuit structure that can include a top thermally conductive layer, a middle electrically insulating layer, a bottom thermally conductive layer, and a plurality of light emitting diodes mounted on the top layer. The LED lighting system can further include a housing substrate and a mounting structure. The mounting structure can be configured to suspend the layered circuit structure above the housing substrate with an air gap disposed in between the bottom thermally conductive layer of the flexible layered circuit structure and the housing substrate. The distance between the layered circuit structure and the support layer can be at least about 0.5 mm. Other embodiments are also included herein.

A flexible circuit board having enhanced bending durability and a method for preparing same are provided. The method comprises: forming a signal line and a first ground layer on a first dielectric body and forming a second ground layer on a bottom side of the first dielectric body; preparing a second dielectric body; preparing a first bonding sheet and a first protective sheet which is connected to one end of the first bonding sheet or of which one or more parts are overlapped on one end of the first bonding sheet; bonding the second dielectric body onto the first dielectric body by means of the first bonding sheet; forming a via hole such that the first ground layer and the second ground layer are conducted; and cutting in a width direction the second dielectric body placed on the first protective sheet.

A driver IC film unit including a flexible film, a driver IC on a first surface of the flexible film and configured to receive an input signal and convert the input signal into an image signal for a display panel, at least first to third pad units, on the first surface of the flexible film, configured to electrically connect the driver IC and the flexible film, and at least first to third wire units, on the first surface of the flexible film, electrically connected to the at least first to third pad units, wherein at least one wire unit among the at least first to third wire units is configured to be extended to a second surface facing the first surface via a first via hole passing through the flexible film, and is configured to include a cut portion of wire corresponding to an edge of the flexible film.

A method for manufacturing a printed-wiring assembly is provided. The method includes a first step of forming a first pattern of printed wiring extending to an end face of a substrate by copper or silver on the substrate. The method includes a second step of cutting the first pattern into a first portion on the end face side from a predetermined position and a second portion on the inner side of the predetermined position, and the cut surface in the second portion is inclined by a predetermined angle with respect to a surface perpendicular to the substrate. The method further includes a third step of forming a protective layer of the second portion so as to cover the cut surface.

Provided is a frame assembly for fixing a plurality of stacked battery cells. The frame assembly may include: a frame including an upper surface, a first side surface connected to a first end of the upper surface and a second side surface connected to a second end of the upper surface, the frame being configured to enclose the plurality of battery cells; a plurality of first bus bars disposed on the first side surface; a plurality of second bus bars disposed on the second side surface; and a flexible printed circuit board disposed along the upper surface, the first side surface, and the second side surface of the frame, the flexible printed circuit board being configured to sense the plurality of battery cells.