A planar lightwave circuit structure based on a printed circuit board and its manufacturing method are provided. The manufacturing method includes: S1, preparing the printed circuit board; S2, adhering the lower cladding layer to one side of the printed circuit board, and then annealing process carried out; S3, jetting a lightwave circuit material on an upper surface of the lower cladding layer in a predetermined route through an electrohydrodynamic jet printing device to form lightwave circuit lines to be cured, the lightwave circuit material being a slurry containing silver ions and an ultraviolet (UV) curing agent; S4, curing the lightwave circuit lines through irradiation of UV light, the UV light irradiating onto the lightwave circuit lines through a lens assembly with slits; and S5, depositing an upper cladding layer on the lower cladding layer and the lightwave circuit lines, and then solidifying treatment carried out.

An electromagnetic wave transmission board proofed against internal signal leakage includes an inner plate, a first outer plate, a second outer plate, a first plate bump, a first conductive bump, a second plate bump, and a second conductive bump. The inner plate defines a first through hole with a plated metal layer on the hole wall. The first and second plated bumps are disposed between the first outer and inner plates. The second plate bump and the second conductive bump are disposed between the second outer plate and the inner plate. The plate metal layer, the first plate bump, the first conductive bump, the first outer plate, the second outer plate, the second conductive bump, and the second plated bump jointly form an air-filled chamber. A method for manufacturing the electromagnetic wave transmission board is also provided.

A bonding pad such as for a ball grid array includes a conductive pad having a top surface and a first interface surface in contact with a signal trace of a substrate, and a plating layer having a bottom surface in direct contact with the top surface of the conductive pad. The plating layer includes one or more protrusions extending toward the signal trace in a direction generally parallel to a longitudinal axis of the signal trace. Each of the one or more protrusions includes two parallel sidewalls extending upwardly from the bottom surface of the plating layer, and a second interface surface contiguous with the bottom surface of the plating layer. The second interface surface is positioned over and in direct contact with a top surface of the signal trace. The protrusions prevent the connection to the signal trace from being compromised.

The disclosure relates to a machining station for machining platelike workpieces (1) by means of at least one tool (10, 13, 14). The machining station has a measuring device (16) for acquiring data relating to the position of bores, a drill (10, 13, 14) for generating bores in the workpiece (1), and a data processor (17) for processing data of the at least one measuring device (16) and/or for controlling the at least one drill (10, 13, 14). The data processor (17) is here suitable and set up for performing an adjustment between a desired drilling position and/or a desired bore depth and an actual position and/or actual depth as determined by the at least one measuring device (16) for a bore present in the workpiece (1), and adapting the drilling position and/or bore depth for generating bores by means of the at least one drill (10, 13, 14).

A printed circuit board and/or an electronic device including the same are provided. The printed circuit board and/or an electronic device includes at least one insulation layer including a first rigid region and a flexible region extending from the first rigid region, at least one first circuit pattern disposed on one surface of the at least one insulation layer to at least partially transverse the flexible region from the first rigid region, and at least one conductive pad formed at least partially on a surface of the first circuit pattern in the first rigid region, wherein the flexible region may be configured to flexibly deform more than the first rigid region.

A die bonding method for a micro-LED. The method includes plating tin at a die bonding position of a printed circuit board (PCB) to obtain a tin-plated layer; adding a protective layer and a flux layer on the tin-plated layer in sequence to obtain a pretreated PCB; and transferring a flip-chip micro-LED to the pretreated PCB, reflowing and die bonding to complete die bonding of the micro-LED.

A current introduction terminal includes a board made of resin. The board has a first face and a second face opposite each other. The board hermetically separates environments of different air pressures from each other. A plurality of through via holes corresponding both to a plurality of metal terminals of a first surface-mount connector to be mounted on the first face and to a plurality of metal terminals of a second surface-mount connector to be mounted on the second face are formed to penetrate between the first and second faces, and then hole parts of the through via holes are filled with resin.

A printed wiring board includes a first resin insulating layer, a conductor layer on the first resin insulating layer, and a second resin insulating layer formed on the first resin insulating layer such that the second resin insulating layer is covering the conductor layer. The conductor layer includes a first circuit having a width of 15 μm or less and a rectangular cross-sectional shape, a second circuit having a trapezoidal cross-sectional shape, a third circuit, a fourth circuit, a fifth circuit, and a sixth circuit, a space between the first and third circuits has a width of 14 μm or less, a space between the first and fourth circuits has a width of 14 μm or less, a space between the second and fifth circuits has a width of 20 μm or more, and a space between the second and sixth circuits has a width of 20 μm or more.

A method of manufacturing a component carrier includes: (i) embedding a poorly adhesive structure in a stack, wherein the stack comprises at least one electrically conductive layer structure and/or at least one electrically insulating layer structure; (ii) forming a cavity in the stack by removing a stack piece, wherein the stack piece is in part delimited by the poorly adhesive structure; and (iii) selectively exposing a bottom of the cavity by partially removing the poorly adhesive structure. A corresponding component carrier includes analogous features.

A multilayer printed circuit board is provided. The multilayer printed circuit board includes a core, a first conductive layer coupled to the core, an insulating layer covering the first conductive layer, and a second conductive layer spaced from the first conductive layer by the insulating layer. The first conductive layer includes a first portion having a first thickness and a second portion having a second thickness greater than the first thickness. The second conductive layer is electrically coupled to the second portion of the first conductive layer by a conductive via extending through the insulating layer.