A semiconductor package module is provided. The semiconductor package module may prevent dropout of a large-scale device from a module substrate by improving bonding strength between the module substrate and a part, and perform assembling parts on a top surface and a bottom surface of the module substrate, simultaneously. The semiconductor package module includes: a module substrate; at least one first electric/electronic device mounted on the module substrate by using surface mount technology (SMT); a plurality of passive devices mounted on the module substrate; and at least one second electric/electronic device mounted on the module substrate by using SMT and a resin film adhesive, the at least one second electric/electronic device having a size or a weight greater than a size or a weight of the at least one first electric/electronic device.

A manufacturing method of a display device includes: loading, on a stage, a panel assembly including: a display panel drivable to display an image, and first and second printed circuit boards attached to the display panel, end portions of the first and second printed circuit boards overlapping each other; providing a jet of air to the overlapping end portion of the second printed circuit board to raise the overlapping end portion away from and expose the end portion of the first printed circuit board; fixing the raised end portion away from the exposed end portion of the first printed circuit board; pre-processing the exposed end portion of the first printed circuit board; and aligning a distal end of the pre-processed end portion of the first printed circuit board and a distal end of the end portion of the second printed circuit board.

A method of this invention is for manufacturing a circuit board in which terminal fittings and electronic components are provided on a first surface of a main substrate that has the first surface and a second surface, a sub substrate that has a first surface and a second surface is arranged on the second surface side of the main substrate, and the sub substrate and the main substrate are connected by relay terminals. The main substrate and the sub substrate are formed in advance in a state of being connected in the same plane. During the method, the main and sub substrate are initially physical connected, at which time electrical components are attached to at least the main substrate. After physically separating the main and sub substrates, they are electrically connected.

A method for manufacturing a double-sided wiring circuit board includes a first step of preparing a laminate and a second step. The laminate includes a metal core layer, insulating layers, and conductor layers. The insulating layer has a region and an opening that are adjacent to each other. The insulating layer has a region including a part facing the region in a thickness direction, and an opening adjacent to the region. The conductor layer includes a wiring portion and a conductive portion. In the second step, the first and second etching treatments for etching the metal core layer through the openings are carried out to form a via portion having a periphery surrounded by a space, extending between the regions, and connected to the conductive portions.

A method for manufacturing includes coating a substrate (22) with a matrix (28) containing a material to be patterned on the substrate. A pattern (42) is fixed in the matrix by directing an energy beam to impinge on the coated substrate so as to fix the pattern in the matrix without fully sintering the pattern. The matrix remaining on the substrate outside the fixed pattern is removed, and after removing the matrix, the material in the pattern is sintered.

A laminate and method for producing the laminate are provided for contacting at least one electronic component. An insulating layer is laminated between first and second metal layers electrically contacted to each other in at least one contact region. At least one recess in the contact region is generated with at least one embossing and/or bulging in the first metal layer. The distance between the two metal layers is reduced, such that dimensions of the embossing/bulging are sufficient for taking up the electronic component, which is inserted and connected into the embossing/bulging in a conductive manner therein. The electronic component is taken up in the embossing/bulging entirely with respect to its circumference and at least partly with respect to the height (H) of the electronic component. The laminate may be used as a circuit board, sensor, LED lamp, mobile phone component, control, or regulator.

An inductor comprises a base having a top surface, a bottom surface, and at least one side surface. The top surface is spaced from the bottom surface. The at least one side surface connects the top surface to the bottom surface. A core is located on the top surface and coupled to the base. At least one coil extends helically about the core. The at least one coil has at least one end extending outwardly from said core. At least one lead is coupled to the at least one coil and extending outwardly from the base in a coplanar relationship with the bottom surface. A circuit card assembly including the inductor and a method of manufacturing the circuit card assembly are also disclosed herein.