Abstract: A semiconductor package includes a set of stud bumps, which can be formed by wire bonding technology and can be bonded or joined to a semiconductor element to form a stacked package assembly. Since the process of bonding the semiconductor element to the stud bumps can be carried out without reflow, an undesirable deformation resulting from high temperatures can be controlled or reduced.

Abstract: A substrate having single patterned metal layer includes a patterned base having at least a plurality of apertures, the patterned metal layer disposed on the patterned base, and a first surface finish layer. Parts of the lower surface of the patterned metal layer are exposed by the apertures of the patterned base to form a plurality of first contact pads for downward electrical connection externally, and parts of the upper surface of the patterned metal layer function as a plurality of second contact pads for upward electrical connection externally. The first surface finish layer is disposed at least on one or more surfaces of the second contact pads, and the first surface finish layer is wider than the second contact pad beneath. A package applied with the substrate disclosed herein further comprises at least a die conductively connected to the second contact pads of the substrate.

Abstract: A package structure including a circuit substrate, at least a chip, leads and an encapsulant is provided. The circuit substrate has a first surface, a second surface opposite to the first surface, and contacts disposed on the first surface. The chip is disposed on the second surface of the circuit substrate and electrically connected to the circuit substrate. The leads are disposed on the periphery of the second surface and surround the chip. Each lead has an inner lead portion and an outer lead portion and is electrically connected to the circuit substrate via the inner lead portion. The encapsulant encapsulates the circuit substrate, the chip and the inner lead portion and exposes the first surface of the circuit substrate and the outer lead portion, wherein the upper surface of the encapsulant and the first surface of the circuit substrate are coplanar with each other.

Abstract: The present invention relates to a semiconductor device with a plurality of mark through substrate vias, including a semiconductor substrate, a plurality of original through substrate vias and a plurality of mark through substrate vias. The original through substrate vias and the mark through substrate vias are disposed in the semiconductor substrate and protrude from the backside surface of the semiconductor substrate. The mark through substrate vias are added at a specific position and/or in a specific pattern and serve as a fiducial mark, which facilitates identifying the position and direction on the backside surface. Thus, the redistribution layer (RBL) or the special equipment for achieving the backside alignment (BSA) is not necessary.

Abstract: The present invention relates to a semiconductor package and a method for making the same. The semiconductor package includes a substrate, a first passivation layer, a first metal layer, a second passivation layer, a second metal layer and a third metal layer. The substrate has a surface having at least one first pad and at least one second pad. The first passivation layer covers the surface of the substrate and exposes the first pad and the second pad. The first metal layer is formed on the first passivation layer and is electrically connected to the second pad. The second passivation layer is formed on the first metal layer and exposes the first pad and part of the first metal layer. The second metal layer is formed on the second passivation layer and is electrically connected to the first pad. The third metal layer is formed on the second passivation layer and is electrically connected to the first metal layer.

Abstract: An embedded circuit substrate comprising: a core structure having a first surface and a second surface opposite to each other; a first patterned conductive layer disposed on the first surface and embedded in the core structure; a second patterned conductive layer disposed on the second surface and embedded in the core structure; and a plurality of conductive blocks disposed in the core structure for conducting the first patterned conductive layer and the second patterned conductive layer is provided. Furthermore, a manufacturing method of an embedded circuit substrate is also provided.

Abstract: A circuit board including a substrate, a conductive pattern and a solder mask layer is provided. The conductive pattern includes a pad, a tail trace and a signal trace. The tail trace connects with the edge of the pad and the signal trace connects with the edge of the pad. An angle between a portion of the signal trace neighboring the pad and the tail trace is larger than 0 degree and smaller than 180 degree. The solder mask layer is disposed on the substrate and covers a portion of conductive pattern. The solder mask layer has an opening exposing the whole pad.

Abstract: A circuit carrier suitable for being connected with a bump is provided. The circuit carrier includes a substrate and at least one bonding pad. The substrate has a bonding pad disposed on a surface thereof for being connected with the bump. A brown-oxide layer is disposed on a surface of the bonding pad.

Abstract: Described herein are wafer-level semiconductor device packages with EMI shielding and related methods. In one embodiment, a semiconductor device package includes: (1) a semiconductor device; (2) a package body covering lateral surfaces of the semiconductor device, a lower surface of the package body and a lower surface of the semiconductor device defining a front surface; (3) a set of redistribution layers disposed adjacent to the front surface, the set of redistribution layers including a grounding element that includes a connection surface electrically exposed adjacent to at least one lateral surface of the set of redistribution layers; and (4) an EMI shield disposed adjacent to the package body and electrically connected to the connection surface of the grounding element. The grounding element provides an electrical pathway to ground electromagnetic emissions incident upon the EMI shield.

Abstract: A substrate structure is provided. The substrate structure includes a substrate, a first insulation layer, a conductive part, a second insulation layer, a seed layer and a conductive layer. The substrate has a first circuit pattern layer and a second circuit pattern layer, which are located on two opposite surfaces of the substrate respectively. The first insulation layer formed on the first circuit pattern layer has a first insulation hole, which exposes a first opening in the outer surface of the first insulation layer. The conductive part formed on the first insulation hole for electrically connecting with a chip is enclosed by the edge of the first opening. The second insulation layer formed on the second circuit pattern layer has a second insulation hole in which the seed layer is formed. The conductive layer is formed on the seed layer for electrically connecting with a circuit board.

Abstract: A chip module and a fabricating method thereof are provided. Firstly, a substrate is provided. Next, a chip is assembled on the substrate and electrically connected with the substrate. Afterward, a plurality of passive units is assembled on the substrate in the style of encircling the chip. Then, a first glue structure is filled between the passive units so that an encircled area is defined by the first glue structure and the passive units. Then, a second glue structure is filled in the encircled area so that the chip is covered by the second glue structure.

Abstract: In one embodiment, a method of forming a semiconductor device package includes: (1) providing a carrier and a semiconductor device including an active surface; (2) forming a first redistribution structure including a first electrical interconnect extending laterally within the first structure and a plurality of second electrical interconnects extending vertically from a first surface of the first interconnect, each second interconnect including a lower surface adjacent to the first surface and an upper surface opposite the lower surface; (3) disposing the device on the carrier such that the active surface is adjacent to the carrier; (4) disposing the first structure on the carrier such that the upper surface of each second interconnect is adjacent to the carrier, and the second interconnects are positioned around the device; and (5) forming a second redistribution structure adjacent to the active surface, and including a third electrical interconnect extending laterally within the second structure.

Abstract: The present invention relates to a semiconductor device and a semiconductor package having the same. The semiconductor device includes a semiconductor substrate, a backside dielectric layer, a plurality of first backside under ball metal (UBM) pads and a first backside UBM plane. The backside dielectric layer is disposed adjacent to a backside surface of the semiconductor substrate. The first backside UBM pads are disposed on the backside dielectric layer. The first backside UBM plane is disposed on the backside dielectric layer, and has a plurality of through holes. The first backside UBM pads are located within the through holes, and a gap is between the first backside UBM plane and the first backside UBM pads. Whereby, the cost for forming the first backside UBM pads and the first backside UBM plane is relatively low.

Abstract: The present invention relates to a semiconductor package and a method for making the same. The semiconductor package includes a base material, a first metal layer, a first dielectric layer, a first upper electrode and a first protective layer. The first metal layer is disposed on a first surface of the base material, and includes a first inductor and a first lower electrode. The first dielectric layer is disposed on the first lower electrode. The first upper electrode is disposed on the first dielectric layer, and the first upper electrode, the first dielectric layer and the first lower electrode form a first capacitor. The first protective layer encapsulates the first inductor and the first capacitor. Whereby, the first inductor and the first lower electrode of the first capacitor are disposed on the same layer, so that the thickness of the product is reduced.

Abstract: A chip package structure includes a substrate, a die, and a package body. The substrate includes a single patterned, electrically conductive layer, and a patterned dielectric layer adjacent to an upper surface of the electrically conductive layer. A part of a lower surface of the electrically conductive layer forms first contact pads for electrical connection externally. The patterned dielectric layer exposes a part of the upper surface of the electrically conductive layer to form second contact pads. The electrically conductive layer exposes the lower surface of the patterned dielectric layer on a lower periphery of the substrate. The die is electrically connected to the second contact pads, the patterned dielectric layer and the die being positioned on the same side of the electrically conductive layer. The package body is disposed adjacent to the upper surface of the electrically conductive layer and covers the patterned dielectric layer and the die.

Abstract: Described herein are semiconductor device packages with EMI shielding and related methods. In one embodiment, a semiconductor device package includes a circuit substrate, an electronic device, an encapsulant, and a conductive coating. The circuit substrate includes a carrying surface, a bottom surface, a lateral surface extending between the carrying surface and the bottom surface, a conductive layer, and a grounding ring. The grounding ring is in a substantially continuous pattern extending along a border of the circuit substrate, is exposed at a lateral surface of the circuit substrate, and is included in the conductive layer. The electronic device is disposed adjacent to the carrying surface and is electrically connected to the conductive layer of the circuit substrate. The encapsulant is disposed adjacent to the carrying surface and encapsulates the electronic device. The conductive coating is applied to the encapsulant and the grounding ring.

Abstract: The present invention relates to a semiconductor package having at least one first layer chip, a plurality of first metal bumps, at least one second layer chip and a package body. The first layer chip includes a first active surface upon which the first metal bumps are disposed and a plurality of first signal coupling pads disposed adjacent to the first active surface. The second layer chip is electrically connected to the first layer chip, and includes a second active surface that faces the first active surface and a plurality of second signal coupling pads. The second signal coupling pads are capacitively coupled to the first signal coupling pads so as to provide proximity communication between the first layer chip and the second layer chip. The package body encapsulates the first layer chip, the first metal bumps, and the second layer chip, and the first metal bumps are partially exposed.

Abstract: The present disclosure relates to a semiconductor process, a semiconductor element and a package having a semiconductor element. The semiconductor element includes a base material and at least one through via structure. The base material has a first surface, a second surface, at least one groove and at least one foundation. The groove opens at the first surface, and the foundation is disposed on the first surface. The through via structure is disposed in the groove of the base material, and protrudes from the first surface of the base material. The foundation surrounds the through via structure. Whereby, the foundation increases the strength of the through via structure, and prevents the through via structure from cracking.

Abstract: A cutting tool suitable for cutting a workpiece placed on a photocurable adhesive layer is provided. The cutting tool includes a main body, a cutting layer and a light emitting material. The cutting layer is disposed on a surface of the main body and is applicable in cutting the workpiece. The light emitting material is disposed inside the cutting layer or between the main body and the cutting layer. The light emitting material is suitable for emitting a light capable of curing the photocurable adhesive layer adjacent to a cutting path as the workpiece is cut by the cutting layer.

Abstract: A circuit board, a chip package structure and a fabrication method of the circuit board are provided. By applying the fabrication method, a plurality of conductive channels can be formed in a single through hole of the circuit substrate. Unlike the conductive channels respectively formed in the through holes according to the related art, the conductive channels of the proposed circuit board can be formed in a single through hole. As such, it is conducive to the expansion of available layout area of the circuit board, the increase in layout flexibility, and the improvement of layout density of the circuit board.