Abstract: An electronic package and a method for fabricating the same are provided. The method includes disposing on a carrier an electronic component having a plurality of conductors, encapsulating the electronic component with an encapsulant, and disposing an electronic device on the encapsulant. The electronic device and the carrier are electrically connected through the conductors, thereby reducing the overall thickness of the electronic package.

Abstract: Provided is a substrate structure including a substrate body, electrical contact pads and an insulating protection layer disposed on the substrate body, wherein the insulating protection layer has openings exposing the electrical contact pads, and at least one of the electrical contact pads has at least a concave portion filled with a filling material to prevent solder material from permeating along surfaces of the insulating protection layer and the electric contact pads, thereby eliminating the phenomenon of solder extrusion. Thus, bridging in the substrate structure can be eliminated even when the bump pitch between two adjacent electrical contact pads is small. As a result, short circuits can be prevented, and production yield can be increased.

Abstract: This present disclosure provides an electronic package and a method for manufacturing the same. An antenna board with a limiter is stacked on a circuit board. A support body for holding the antenna board and the circuit board in place is provided between the antenna board and the circuit board, such that in the process of forming the support body, the limiter stops the flow of an adhesive material of the support body, and the adhesive material of the support body is prevented from overflowing onto an antenna structure of the antenna board to make sure that the antenna of the antenna board functions properly.

Abstract: The present disclosure provides a method for manufacturing an electronic package, with an electronic component bonded to a carrier structure by means of solder tips formed on conductive bumps, wherein the solder tips do not require a reflow process to be in contact with the carrier structure, thereby allowing the conductive bumps to have an adequate amount of solder tips formed thereon and thus precluding problems such as cracking and collapsing of the solder tips.

Abstract: A package stacked structure and a method for fabricating the same are provided. The method includes providing a wiring structure disposed with a carrier and a carrier structure provided with an electronic component. The wiring structure is bonded to the carrier structure via a plurality of conductive elements. An encapsulating layer is formed between the wiring structure and the carrier structure and encapsulates the conductive elements and the electronic component. The carrier is then removed. With the arrangement of the carrier, the structural strength of the wiring structure is improved, and warpage of the wiring structure is prevented before stacking the wiring structure onto the carrier structure.

Abstract: The present disclosure provides a method for manufacturing an electronic package, with an electronic component bonded to a carrier structure by means of solder tips formed on conductive bumps, wherein the solder tips do not require a reflow process to be in contact with the carrier structure, thereby allowing the conductive bumps to have an adequate amount of solder tips formed thereon and thus precluding problems such as cracking and collapsing of the solder tips.

Abstract: Provided is a substrate structure including a substrate body, electrical contact pads and an insulating protection layer disposed on the substrate body, wherein the insulating protection layer has openings exposing the electrical contact pads, and at least one of the electrical contact pads has at least a concave portion filled with a filling material to prevent solder material from permeating along surfaces of the insulating protection layer and the electric contact pads, thereby eliminating the phenomenon of solder extrusion. Thus, bridging in the substrate structure can be eliminated even when the bump pitch between two adjacent electrical contact pads is small. As a result, short circuits can be prevented, and production yield can be increased.

Abstract: An electronic package is provided, which includes: a first substrate; a first electronic component disposed on the first substrate; a second substrate stacked on the first substrate through a plurality of first conductive elements and a plurality of second conductive elements and bonded to the first electronic component through a bonding layer; and a first encapsulant formed between the first substrate and the second substrate. The first conductive elements are different in structure from the second conductive elements so as to prevent a mold flow of the first encapsulant from generating an upward pushing force during a molding process and hence avoid cracking of the second substrate. The present disclosure further provides a method for fabricating the electronic package.

Abstract: An electronic package and a method for fabricating the same are provided. A resist layer and a support are formed on a first substrate having a first antenna installation area. A second substrate having a second antenna installation area is laminated on the resist layer and the support. The resist layer is then removed. The support keeps the first substrate apart from the second substrate at a distance to ensure that the antenna transmission between the first antenna installation area and the second antenna installation area can function normally.

Abstract: The present disclosure provides a method for manufacturing an electronic package, with an electronic component bonded to a carrier structure by means of solder tips formed on conductive bumps, wherein the solder tips do not require a reflow process to be in contact with the carrier structure, thereby allowing the conductive bumps to have an adequate amount of solder tips formed thereon and thus precluding problems such as cracking and collapsing of the solder tips.

Abstract: An electronic package and a method for fabricating the same are provided. The method includes: forming a circuit structure on an encapsulant; embedding a first electronic component and a plurality of conductive posts in the encapsulant; and disposing a second electronic component on the circuit structure. Since the first and second electronic components are arranged on opposite sides of the circuit structure, the electronic package can provide multi-function and high efficiency.

Abstract: The disclosure provides a substrate construction applicable to a 3D package, including a silicon substrate for carrying a chip on an upper side thereof, and a circuit structure formed underneath the silicon substrate for being connected to solder balls via conductive pads of the circuit structure, thereby obtaining the same specification of the conductive pads as ball-planting pads of conventional package substrates and avoiding the manufacturing and use of conventional package substrates.

Abstract: An electronic package and a method for fabricating the same are provided. The method includes forming a filling material, such as an underfill, between a carrier and a plurality of electronic components and filling the filling material in a space between the electronic components to form a spacing portion. The spacing portion has a first segment and a second segment separated from each other to serve as a stress buffer zone. Therefore, when an encapsulation layer encapsulating the electronic components is subsequently ground, the present disclosure can effectively prevent the electronic components from being cracked due to stresses induced by the external grinding force.

Abstract: An electronic package and a method for fabricating the same are provided. The method includes forming a filling material, such as an underfill, between a carrier and a plurality of electronic components and filling the filling material in a space between the electronic components to form a spacing portion. The spacing portion has a first segment and a second segment separated from each other to serve as a stress buffer zone. Therefore, when an encapsulation layer encapsulating the electronic components is subsequently ground, the present disclosure can effectively prevent the electronic components from being cracked due to stresses induced by the external grinding force.

Abstract: An electronic package and a method for fabricating the same are provided. The method includes disposing on a carrier an electronic component having a plurality of conductors, encapsulating the electronic component with an encapsulant, and disposing an electronic device on the encapsulant. The electronic device and the carrier are electrically connected through the conductors, thereby reducing the overall thickness of the electronic package.

Abstract: An electronic package and a method for fabricating the same are provided. The method includes stacking an antenna board on a circuit board, and disposing between the antenna board and the circuit board a supporting body securing the antenna board and the circuit board. As such, during a packaging process, the distance between the antenna board and the circuit board is kept unchanged due to the supporting body, thus ensuring that the antenna board operates properly and improving the product yield.

Abstract: An electronic package and a method of fabricating the same are provided. The method includes disposing an electronic component on a first side of an interposer, forming a first encapsulant on the first side of the interposer to encapsulate the electronic component, forming a plurality of conductive elements on a second side of the interposer, and forming a second encapsulant on the second side of the interposer to encapsulate the conductive elements. During thermal cycling of the electronic package, shrinkage forces of the first encapsulant and the second encapsulant can offset each other so as to mitigate warping of the interposer.

Abstract: The present disclosure provides a package stack structure and a method for manufacturing the same. The method is characterized by stacking coreless circuit portions on the board of an electronic component to reduce the overall thickness of the package stack structure.

Abstract: The disclosure provides a substrate construction applicable to a 3D package, including a silicon substrate for carrying a chip on an upper side thereof, and a circuit structure formed underneath the silicon substrate for being connected to solder balls via conductive pads of the circuit structure, thereby obtaining the same specification of the conductive pads as ball-planting pads of conventional package substrates and avoiding the manufacturing and use of conventional package substrates.

Abstract: A packaging substrate is provided, which includes: a substrate body having a first region with a plurality of conductive pads and a second region adjacent to the first region, and a material layer formed on the second region to prevent the substrate body from warping. An electronic package having the packaging substrate is also provided.