The present disclosure provides a display module and a method for coating the same, which can prevent and/or reduce the occurrence of black seam between display modules that are arranged adjacent to each other. According to an example aspect of the present disclosure, a display module includes a printed circuit board; a plurality of luminous elements arranged at predetermined intervals on the printed circuit board; and a coating layer comprising a coating disposed between the respective luminous elements, disposed around side surfaces of the respective luminous elements positioned at an outermost, and formed to have a height that is substantially equal to a height of the side surfaces of the luminous elements, the coating being configured to block side light of the respective luminous elements.

A printed substrate includes a land that is to be soldered. The land includes a plating film that defines a surface of the land. The plating film includes a metal as a main constituent and a pi-acceptor molecule that is dispersed in the plating film. The pi-acceptor molecule has pi-acceptability and causes ligand field splitting equal to or greater than that of 2,2′-bipyridyl in spectrochemical series. A content of the pi-acceptor molecule in the plating film is equal to or greater than 0.1 weight percent, in terms of carbon atoms, with respect to the metal of the plating film.

An article for a power inverter, includes a multilayer printed circuit board having a first and second electrically conductive wiring layer and at least a first dielectric layer interposed between the first and second electrically conductive wiring layers. Each conductive wiring layer includes a common input and output line, the common input and output lines at least partially overlapping one another in a projection along a thickness of the multilayer printed circuit board. A set of input mounting pads is carried by the first common input line and a set of input mounting pads is carried by the second common input line, the input mounting pads of the second set of input mounting pads are interleaved with the input mounting pads of the first set of input mounting pads along a first axis. The article further includes a set output mounting pads carried by the common output line.

The disclosure provides an electronic assembly that includes: a carrier element, a circuit carrier having a number of electronic components, a circuit board, which is electrically conductively connected to the circuit carrier, and a covering element for covering the circuit carrier. The covering element is arranged on one flat side of the circuit board and the carrier element is arranged on an opposite flat side of the circuit board. The circuit board is welded respectively to the carrier element and to the covering element. The disclosure further relates to a method for producing such an electronic assembly.

A camera module and an array camera module based on an integral packing process are disclosed. The camera module or each of the camera module units of the array camera module includes a circuit board, an integral base, a photosensitive element operatively connected to the circuit board, a lens, a light filter holder installed at the integral base and a light filter installed at the light filter holder. The light filter is not required to be directly installed to the integral base, so that the light filter is protected and the requiring area of the light filter is reduced.

An embedded magnetic component transformer device includes primary, secondary, and auxiliary windings that are defined by conductive vias connected by conductive traces. The conductive traces and vias of the auxiliary winding are arranged between the conductive traces and vias of respective first and second portions of the primary winding, so that the auxiliary winding is provided substantially in the center of the width of the PCB. Power connections are provided at respective opposing edges of the device, and surface mounted transistors are provided close to the primary winding portions between the auxiliary winding and the edge of the device. The device provides an efficient utilization of the surface conductive traces such that large areas of the surface remain for other functions, such as ground plates. The thermal properties of the device are balanced by distributing the transistors and the power connections.

A module includes a substrate, a component mounted on a top surface that is one principal surface of the substrate, a first shielding film provided on a top surface and a side surface of the component, a sealing resin provided on the top surface of the substrate and seals the component, and a second shielding film provided on a top surface of the sealing resin. A hole is provided on a top surface of the sealing resin, to reach at least a part of the first shielding film. The second shielding film disposed in the hole is brought into contact with the first shielding film at positions facing a top surface and a side surface of the component.

The disclosure provides an electronic device including a substrate, at least one conductive composite structure, and an electronic element. The at least one conductive composite structure is disposed on the substrate. The at least one conductive composite structure includes a first metal layer, a second metal layer, and a third metal layer. The second metal layer is located between the first metal layer and the third metal layer, and the thickness of the second metal layer ranges from 0.5 μm to 12 μm. The electronic element is disposed on the at least one conductive composite structure and bonded to the at least one conductive composite structure.

To improve, in an encapsulated circuit module having a metal shield layer covering a surface of a resin layer containing filler, a shielding property of the shield layer against electromagnetic waves.

The encapsulated circuit module has a substrate 100 on which electronic components are mounted, covered with a first resin 400. A surface of the first resin 400 is covered with a shield layer 600 including a first metal covering layer 610 made of copper or iron and a second metal covering layer 620 made of nickel. Each of the first metal covering layer 610 and the second metal covering layer 620 is thicker than 5 μm.

An electronic circuit may include an elastomeric substrate with an electronic die attached to the elastomer substrate at a first substrate area and one or more meander traces electrically coupled to the electronic die and encapsulated in the elastomer substrate at a second substrate area that is adjacent to the first substrate area. An inelastic, non-electronic, structural brace may be attached to the elastomeric substrate in the first substrate area.