A chip package is provided. The chip package includes a substrate structure. The substrate structure includes a redistribution structure, a third insulating layer, and a fourth insulating layer. The first wiring layer has a conductive pad. The conductive pad is exposed from the first insulating layer, and the second wiring layer protrudes from the second insulating layer. The third insulating layer is under the first insulating layer of the redistribution structure and has a through hole corresponding to the conductive pad of the first wiring layer. The conductive pad overlaps the third insulating layer. The fourth insulating layer disposed between the redistribution structure and the third insulating layer. The chip package includes a chip over the redistribution structure and electrically connected to the first wiring layer and the second wiring layer.

An IC package, an electronic assembly, and methods of preventing warpage of components of an electronic assembly during fabrication of the electronic assembly are shown. An IC package including an adhesive disposed at or near at least one of four corners of a die of the IC package is shown. An electronic assembly including an IC package that includes an adhesive disposed at or near at least one of four corners of a second surface of a first substrate is shown. Methods of preventing warpage of components of an electronic assembly during fabrication of the electronic assembly that include applying an adhesive to at least one of four corners of a first surface of a first component are shown.

A silicon integrated circuit. In some embodiments, the silicon integrated circuit includes a first conductive trace, on a top surface of the silicon integrated circuit, a dielectric layer, on the first conductive trace, and a second conductive trace, on the dielectric layer, connected to the first conductive trace through a first via.

The present disclosure provides a semiconductor package structure and a method of manufacturing the same. The semiconductor package structure includes a substrate, a first electronic component, an interlayer, a third electronic component and an encapsulant. The first electronic component is disposed on the substrate. The first electronic component has an upper surface and a lateral surface and a first edge between the upper surface and the lateral surface. The interlayer is on the upper surface of the first electronic component. The third electronic component is attached to the upper surface of the first electronic component via the interlayer. The encapsulant encapsulates the first electronic component and the interlayer. The interlayer does not contact the lateral surface of the first electronic component.

A semiconductor device (1,21) includes a solid state device (2,22), a semiconductor chip (3) that has a functional surface (3a) on which a functional element (4) is formed and that is bonded on a surface of the solid state device with the functional surface thereof facing the surface of the solid state device and while maintaining a predetermined distance between the functional surface thereof and the surface of the solid state device, an insulating film (6) that is provided on the surface (2a, 22a) of the solid state device facing the semiconductor chip and that has an opening (6a) greater in size than the semiconductor chip when the surface of the solid state device facing the semiconductor chip is vertically viewed down in plane, and a sealing layer (7) that seals a space between the solid state device and the semiconductor chip.

An apparatus includes a polymer base layer having a surface. A die that includes a fluid manipulation surface that is substantially coplanar with the surface of the polymer base layer. The die includes a control electrode to generate an electric field to perform microfluidic manipulation of fluid across the fluid manipulation surface of the die.

The present disclosure provides a method of transferring an electronic element using a stamping and magnetic field alignment technology and an electronic device including an electronic element transferred using the method. In the present disclosure, a polymer may be simultaneously coated on a plurality of electronic elements using the stamping process, and the polymer may be actively coated on the electronic elements without restrictions on process parameters such as size and spacing of the electronic elements. Moreover, the self-aligned ferromagnetic particles have an anisotropic current flow through which current flows only in the aligned direction. Therefore, the current may flow only vertically between the electronic element and the electrode, and there is no electrical short circuit between a peripheral LED element and the electrode.

A display panel is provided. The display panel includes a frame area, and the frame area includes an array substrate and a color filter substrate. The array substrate includes a fanout area configured to dispose a fanout trace. The color filter substrate is disposed opposite to the array substrate. The color filter substrate includes a gate driver on array (GOA) circuit and a signal trace disposed at a side of the GOA circuit. The GOA circuit is electrically connected to the signal trace. The GOA circuit and the signal trace both overlap the fanout area.

A wiring substrate includes a first substrate and an electronic component mounted on an upper surface of the first substrate. A first pad is formed on an uppermost wiring layer of the first substrate. A connection terminal is formed on the electronic component and is located proximate to the first pad in a plan view. The wiring substrate further includes a connection member formed on the first pad to electrically connect the first pad and the connection terminal. The connection member includes a rod-shaped core and a solder layer, which is coated around the core and joined to the first pad. The solder layer includes a bulge that spreads from the core of the connection member in a planar direction. The bulge is joined to the connection terminal of the electronic component.

The semiconductor device includes at least three semiconductor elements disposed directly or indirectly on a planar member and constituting an upper arm and a lower arm which perform ON and OFF action at mutually differential times; an upper-surface voltage applied region of each semiconductor element is configured to be narrower than an area of the aforementioned whole semiconductor element in planar view; and each semiconductor element is disposed so that the shortest distance between the semiconductor elements constituting the upper arm is formed so as to be longer than the shortest distance between the semiconductor element constituting the upper arm and the semiconductor element constituting the lower arm.