A semiconductor package comprises a substrate, a pad, a first isolation layer, an interconnection layer, and a conductive post. The substrate has a first surface and a second surface opposite the first surface. The pad has a first portion and a second portion on the first surface of the substrate. The first isolation layer is disposed on the first surface and covers the first portion of the pad, and the first isolation layer has a top surface. The interconnection layer is disposed on the second portion of the pad and has a top surface. The conductive post is disposed on the top surface of the first isolation layer and on the top surface of the interconnection layer. The top surface of the first isolation layer and the top surface of the interconnection layer are substantially coplanar.

A semiconductor device including an integrated circuit, a protection layer, and a conductive via is provided. The integrated circuit includes at least one conductive pad. The protection layer covers the integrated circuit. The protection layer includes a contact opening, and the conductive pad is exposed by the contact opening of the protection layer. The conductive via is embedded in the contact opening of the protection layer, and the conductive via is electrically connected to the conductive pad through the contact opening. A method of fabricating the above-mentioned semiconductor device and an integrated fan-out package including the above-mentioned semiconductor device are also provided.

The present disclosure provides a semiconductor structure including a substrate; a redistribution layer (RDL) disposed over the substrate, and including a dielectric layer over the substrate, a conductive plug extending within the dielectric layer, and a bonding pad adjacent to the conductive plug and surrounded by the dielectric layer; and a conductive bump disposed over the conductive plug, wherein the bonding pad is at least partially in contact with the conductive plug and the conductive bump. Further, a method of manufacturing the semiconductor structure is also provided.

Disclosed is a fan-out back-to-back chip stacked package, comprising a back-to-back stack of a first chip and a second chip, an encapsulant, a plurality of vias disposed in the encapsulant, a first redistribution layer and a second redistribution layer. The encapsulant encapsulates the sides of the first chip and the sides of the second chip simultaneously and has a thickness not greater than the chip stacked height to expose a first active surface of the first chip and a second active surface of the second chip. The encapsulant has a first peripheral surface expanding from the first active surface and a second peripheral surface expanding from the second active surface. The first redistribution layer is formed on the first active surface and extended onto the first peripheral surface to electrically connect the first chip to the vias in the encapsulant. The second RDL is formed on the second active surface and extended onto the second peripheral surface to electrically connect the second chip to the vias in the encapsulant. Accordingly, the structure realizes a thin package configuration of multi-chip back-to-back stacking to reduce package warpage.

An electric apparatus may include a plurality of electric patterns arranged on a substrate. Each of the electric patterns may include a pad for connection with a solder ball, an electrical trace laterally extending from a portion of the pad to allow an electrical signal to be transmitted from or to the pad, a first dummy trace laterally extending from other portion of the pad, and a first connection line connecting the first dummy trace to the electrical trace. The first dummy trace may be provided at a position deviated from a straight line connecting the pad to the electrical trace.

A technique which improves the reliability in coupling between a bump electrode of a semiconductor chip and wiring of a mounting substrate, more particularly a technique which guarantees the flatness of a bump electrode even when wiring lies in a top wiring layer under the bump electrode, thereby improving the reliability in coupling between the bump electrode and the wiring formed on a glass substrate. Wiring, comprised of a power line or signal line, and a dummy pattern are formed in a top wiring layer beneath a non-overlap region of a bump electrode. The dummy pattern is located to fill the space between wirings to reduce irregularities caused by the wirings and space in the top wiring layer. A surface protection film formed to cover the top wiring layer is flattened by CMP.

A semiconductor chip includes a body part having a front surface and a rear surface, a plurality of through electrodes penetrating the body part and arranged in a first direction in an array region, a plurality of front surface connection electrodes respectively coupled to the through electrodes over the front surface of the body part, and a plurality of rear surface connection electrodes respectively coupled to the through electrodes over the rear surface of the body part. The array region includes a central region and edge regions positioned on both sides of the central region in the first direction. A center of the front surface connection electrode and a center of the rear surface connection electrode that are positioned in each of the edge regions are positioned at a distance farther from the central region than a center of the corresponding through electrode.

A semiconductor chip includes a body part having a front surface and a rear surface, a plurality of through electrodes penetrating the body part and arranged in a first direction in an array region, a plurality of front surface connection electrodes respectively coupled to the through electrodes over the front surface of the body part, and a plurality of rear surface connection electrodes respectively coupled to the through electrodes over the rear surface of the body part. The array region includes a central region and edge regions positioned on both sides of the central region in the first direction. A center of the front surface connection electrode and a center of the rear surface connection electrode that are positioned in each of the edge regions are positioned at a distance farther from the central region than a center of the corresponding through electrode.

An integrated circuit (IC) chip comprises a plurality of pads and a plurality of bumps. The plurality of pads includes a first pad. The plurality of bumps is disposed on the plurality of pads. The plurality of bumps includes a first bump disposed on the first pad. The first bump as a width that is different than an exposed with of the first pad. The center of the first bump is not aligned with a center of the first pad.

The present invention provides a structure. In an exemplary embodiment, the structure includes a base material, at least one metal pad, where a first surface of the metal pad is in contact with the base material, and a metal pedestal, where the metal pedestal is in contact with the metal pad, where a radial alignment of the metal pad is shifted by an offset distance, with respect to the metal pedestal, such that the metal pad is shifted towards a center axis of the base material, where a first dimension of the metal pad is smaller than a second dimension of the metal pad, where the second dimension is orthogonal to a line running from a center of the metal pad to the center axis of the base material, where the first dimension is parallel to the line.