The present disclosure relates to a display apparatus and an electronic device, relating to the technical field of display. The display apparatus may comprise a display panel, a main circuit board, a bridging circuit board, and a first shielding adhesive tape. The main circuit board may be provided on the back surface of the display panel; the bridging circuit board may be provided at the side of the main circuit board distant from the display panel, and may be connected to the main circuit board in a binding mode; and the first shielding adhesive tape may be provided at the side of the main circuit board distant from the display panel, and expose the bridging circuit board.

A printed circuit board includes a plurality of layers including attachment layers and routing layers; and via patterns formed in the plurality of layers, each of the via patterns including first and second signal vias forming a differential signal pair, the first and second signal vias extending through at least the attachment layers; ground vias extending through at least the attachment layers, the ground vias including ground conductors; and shadow vias located adjacent to each of the first and second signal vias, wherein the shadow vias are free of conductive material in the attachment layers. The printed circuit board may further include slot vias extending through the attachment layers and located between via patterns.

A power module for the controllable electrical power supply of a consumer includes a plurality of housed power semiconductors each with an electrically non-insulated heat discharge surface, a printed circuit board, a heat sink, one or more insulation plates, wherein the printed circuit board is arranged on a side of the power semiconductor in an orthogonal direction opposite the heat sink, wherein the insulation plate is arranged between the housed power semiconductors and a cooling surface of the heat sink, wherein one insulation plate in each case is interlockingly connected by one side to one electrically non-insulated heat discharge surface of a housed power semiconductor and is interlockingly connected by the other side to the heat sink.

An interlayer connective structure is suitable for being formed in a wiring board, in which the wiring board includes two traces and an insulation part between the traces. The insulation part has a through hole. The interlayer connective structure located in the through hole is connected to the traces. The interlayer connective structure includes a column and a pair of protuberant parts. The protuberant parts are located at two ends of the through hole respectively and connected to the column and the traces. The protuberant parts stick out from the outer surfaces of the traces respectively. Each of the protuberant parts has a convex curved surface, in which the distance between the convex curved surface and the axis of the through hole is less than the radius of the through hole.

An electronic-component carrier board includes carrier plates formed in a stack, and insulating layers each disposed between two adjacent ones of the carrier plates. Multiple conductive pins extend through the insulating layers and the carrier plates. Multiple conductive wires equal in length and width are provided. Each conductive wire is connected to one of the conductive pins, covered by one of the insulating layers, disposed between two adjacent ones of the carrier plates, and extends outwardly from the stack of the carrier plates. A wiring method for the electronic-component carrier board is also disclosed.

A component carrier with an electrically insulating layer having a front side and a back side, a first and a second electrically conductive layer covering the front side and the back side of the electrically insulating layer, respectively. A through hole extends through both electrically conductive layers and the electrically insulating layer. An overhang is formed along one of the electrically conductive layers and sidewalls of the electrically insulating layer structure delimiting the through hole. An annular plating layer covers the sidewalls and fills part of the overhang such that a horizontal extension of the overhang after plating is less than 20 μm and/or such that a ratio between a horizontal extension of the overhang after plating and a width of a first window through the first electrically conductive layer and/or a width of a second window through the second electrically conductive layer is smaller than 20%.

A circuit board may include a plurality of electrically-conductive layers separated and supported by layers of insulating material laminated together and a via electrically coupled to a first layer of the circuit board and coupled to a second layer of the circuit board, the via comprising a first via portion comprising electrically-conductive material and having a first diameter and a first depth from a surface of the circuit board and a second via portion comprising electrically-conductive material and having a second diameter smaller than the first diameter and a second depth from the first depth.

A wiring substrate includes a first insulating layer, a first conductor layer, and a plurality of filled vias. The first insulating layer has a first surface and a second surface positioned on a side opposite to the first surface. The first conductor layer is formed on the first surface of the first insulating layer. The plurality of filled vias are formed inside the first insulating layer. The plurality of filled vias each have a structure in which a via hole penetrating the first insulating layer is filled with a metal. The first conductor layer includes a pad. The pad overlaps the plurality of filled vias in a plan view from a thickness direction of the first insulating layer and is connected to the plurality of filled vias.

An electronics module (100), especially a power electronics module, comprising a metal-ceramic substrate (1) serving as a carrier and having a ceramic element (10) and a primary component metallization (21), an insulation layer (40) directly or indirectly connected to the primary component metallization (21), and a secondary component metallization (22) which is connected to the side of the insulation layer (40) facing away from the metal-ceramic substrate (1) and is especially isolated from the primary component metallization (21) using the insulation layer (40), wherein the ceramic element (10) has a first size (L1, D1) and the insulation layer (40) has a second size (L2, D2) and a ratio of the second size (L2, D2) to the first size (L1, D1) has a value smaller than 0.8, to form an island-like insulation layer (40) on the primary component metallization (21).

An electronic device includes a component mounting portion, an electronic component disposed on the component mounting portion, a solder between the component mounting portion and the electronic component, a mounting base member, and a supporting beam connecting the component mounting portion and the mounting base member. The supporting beam has a plurality of bent portions. The supporting beam includes a frame, an outer supporting portion connecting the frame and the mounting base member, and an inner supporting portion connecting the frame and the component mounting portion. The inner supporting portion is shifted from the outer supporting portion along the frame. One of the plurality of bent portions is a connecting portion between the frame and the outer supporting portion. Another of the plurality of bent portions is a connecting portion between the frame and the inner supporting portion.