Abstract: Embodiments of the invention provide a method for fabricating a system in package. In one embodiment, the method comprises preparing a printed circuit board (PCB) strip comprising a plurality of individual PCBs, stacking a plurality of first semiconductor chips and forming an encapsulant on a first surface of a first individual PCB of the plurality of individual PCBs to form a first semiconductor chip stack structure comprising a first semiconductor chip stack, and performing a first test adapted to test one of the first semiconductor chips in the first semiconductor chip stack. The method further comprises flip chip bonding a second semiconductor chip to a second surface of the first individual PCB if the first semiconductor chip stack structure meets a test standard based on a result of the first test, and dividing the first semiconductor chip stack structure to form a system in package.

Abstract: A wiring substrate having variously sized ball pads, a semiconductor package including the wiring substrate, and a stack package using the semiconductor package, to improve board level reliability (BLR) of a semiconductor package or stack package mounted on a mother board are shown. Outer ball pads are formed to have relatively greater surface areas at the corners of the semiconductor package as compared to those at other areas and are formed to have the greatest surface area within a designable range. Additionally, occurrence of cracks may be inhibited at junctions of other solder balls by forming dummy solder pads at the outermost corners among the outer ball pads formed proximate to the corners of the wiring substrate. Stress arising during a board level reliability test is absorbed without product failure at junctions between the dummy solder pads and dummy solder balls.

Abstract: A semiconductor package may include a heat sink. The heat sink may be disposed above and spaced apart from a substrate, which may support a semiconductor chip. The heat sink may have a hole. A liquid molding compound may be provided through the hole of the heat sink to form an encapsulant. The encapsulant may seal the semiconductor chip, leaving an upper portion of the heat sink exposed. A tape supporting the heat sink may be provided on the substrate. The tape may be removed after the encapsulant is provided.

Abstract: A semiconductor wafer includes a plurality of passive device units, which are electrically connected across scribe lines. Passive device chips in the wafer that are adjacent to one another in a first direction are electrically connected in parallel, while passive device units adjacent to one another in a second direction are connected in series. By selecting a number of adjacent passive device units extending in the first and second direction, and separating the selected units from the wafer along the corresponding scribe lines, a passive device chip having a desired electrical characteristic (e.g., capacitance or resistance) can be obtained. Such passive device chips may be assembled in a semiconductor package where they are electrically connected to active devices.

Abstract: Disclosed is a semiconductor device packaging technique that is capable of resolving a problem of instability of bonding wires when stacking a plurality of semiconductor chips. The technique is also capable of realizing a slim, light and small package. The semiconductor device package includes a substrate having a substrate pad on a surface thereof, one or more memory chips stacked on the substrate with each memory chip having a pad connected to a common pin receiving a common signal applied to all the memory chips, an interposer chip stacked on the substrate and having an interconnection wire connected to the memory chip pad, the common pin of each of the memory chips being electrically connected to the interconnection wire via the memory chip pad, and a logic chip stacked on the substrate and having a bypass circuit which electrically connects or disconnects the interconnection wire to or from the substrate pad.

Abstract: Semiconductor packages are provided to prevent a chip, such as a central processing unit (CPU) chip, from being degraded due to hot spot heat generated during the operation of the chip and absorbs thermomechanical stresses in interfaces between the chip, a thermal interface material (TIM) and a lid. The chip is electrically connected, e.g., flip-chip bonded, to a package substrate. The lid is thermally connected to and disposed over a back surface of the chip with the TIM interposed therebetween. A heat dissipation means adjacent the TIM is also located between the lid and the chip to prevent the hot spot effect.

Abstract: Provided is a semiconductor device package in which instability of a bonding wire that may occur when a plurality of semiconductor chips are stacked is prevented and which obtains a light, thin and small structure. The semiconductor device package includes a substrate having a plurality of substrate pads on a top surface of the semiconductor device package and includes a plurality of semiconductor chips stacked on the substrate. Each of the semiconductor chips have a chip pad electrically connected to a common pin, e.g., to which a common signal may be concurrently applied to each of the semiconductor chips. An interposer chip, also stacked on the substrate, has a connecting wire electrically connected to the chip pad, the common pin of each of the semiconductor chips being thereby electrically coupled at the connecting wire via the chip pad, and the connecting wire being thereby electrically connected to the substrate pad.

Abstract: A multi-chip package includes a substrate having first and second substrate pads, ball pads electrically connected to the first and second substrate pads, a first chip attached on the substrate and having first chip pads flip-chip bonded to the first substrate pads, and a second chip attached on the first chip and having second chip pads wire-bonded to the second substrate pads. The second chip may have overhang portions. Solder balls may be formed on the ball pads and act as external connection terminals. A support member may be interposed between the first chip and the second chip to support the overhang portions of the second chip.

Abstract: A method for manufacturing a flip chip package includes preparing an IC chip that includes an active surface on which electrode pads are formed, attaching a heat dissipater to a backside of the IC chip with a thermal interface material (TIM), providing a flux filler layer on a substrate, where the substrate includes a plurality of land pads each corresponding to each of the plurality of electrode pads, and mounting the IC chip to the substrate with the active surface facing the substrate. The method further includes forming metal connectors on each of the corresponding plurality of electrode pads of the IC chip, and forming an electrical interconnection between the land pads of the substrate and the plurality of metal connectors by soldering the metal connectors to the land pads. The heat dissipator may be a hermetic heat spreader having a pair of opposite ends bent toward the substrate, which are hermetically sealed to the substrate.

Abstract: In one embodiment, a semiconductor package comprises a base frame and a lower semiconductor chip electrically coupled to the base frame. The lower semiconductor chip has a first bond pad formed on a top surface thereof. The package further includes an upper semiconductor chip overlying the lower semiconductor chip. The upper semiconductor chip has a third bond pad formed on a bottom surface thereof. The package comprises a first conductive bump and a second conductive bump jointly coupling the first bond pad to the third bond pad.

Abstract: A method of manufacturing a multi-stack package that ensures easy application of a solder paste or a flux. The method includes forming a first package comprising a first substrate on which bumps are arranged and a second package comprising a second substrate on which electrode pads corresponding to the bumps are arranged, applying a solder paste on the bumps of the first package, and electrically connecting the bumps of the first package and the electrode pads of the second package.

Abstract: Semiconductor packages are provided to prevent a chip, such as a central processing unit (CPU) chip, from being degraded due to hot spot heat generated during the operation of the chip and absorbs thermomechanical stresses in interfaces between the chip, a thermal interface material (TIM) and a lid. The chip is electrically connected, e.g., flip-chip bonded, to a package substrate. The lid is thermally connected to and disposed over a back surface of the chip with the TIM interposed therebetween. A heat dissipation means adjacent the TIM is also located between the lid and the chip to prevent the hot spot effect.

Abstract: A multi-chip package may be provided which may include a substrate, on which multiple substrate bonding pads may be formed and under which multiple terminals may be formed, first and second semiconductor chips, which may be deposited on the substrate, and a spacer, which may be formed between the first and second semiconductor chips to have at least power and ground pads. The spacer may be used as passive element, and the first and second semiconductor chips and the power and ground pads of the spacer may be electrically connected. The pads of the semiconductor chip which may be deposited on the spacer may also be electrically connected to substrate bonding pads via the pads which may be formed on the spacer.

Abstract: A semiconductor wafer includes a plurality of passive device units, which are electrically connected across scribe lines. Passive device chips in the wafer that are adjacent to one another in a first direction are electrically connected in parallel, while passive device units adjacent to one another in a second direction are connected in series. By selecting a number of adjacent passive device units extending in the first and second direction, and separating the selected units from the wafer along the corresponding scribe lines, a passive device chip having a desired electrical characteristic (e.g., capacitance or resistance) can be obtained. Such passive device chips may be assembled in a semiconductor package where they are electrically connected to active devices.

Abstract: A multi-chip package, a semiconductor device used therein, and manufacturing method thereof are provided. The multi-chip package may include a substrate having a plurality of substrate bonding pads formed on an upper surface thereof, at least one first semiconductor chip mounted on the substrate, and at least one second semiconductor chip mounted on the substrate where the at least one first semiconductor chip may be mounted. The at least one second semiconductor chip may include at least one three-dimensional space so as to allow the at least one first semiconductor chip to be enclosed within the at least one three-dimensional space. The at least one three-dimensional space may be a cavity, a groove, or a combination thereof.

Abstract: In accordance with the present invention, a chip scale package (CSP) is manufactured at wafer-level. The CSP includes a chip, a conductor layer for redistribution of the chip pads of the chip, one or two insulation layers and multiple bumps, which are interconnected to respective chip pads by the conductor layer and are the terminals of the CSP. In addition, in order to improve the reliability of the CSP, a reinforcing layer, an edge protection layer and a chip protection layer are provided. The reinforcing layer absorbs stress applied to the bumps when the CSP is mounted on a circuit board and used for an extended period, and extends the life of the bumps, and thus, the life of the CSP. The edge protection layer and the chip protection layer prevent external force from damaging the CSP. After forming all elements constituting the CSP on the semiconductor wafer, the semiconductor wafer is sawed to produce individual CSPs.

Abstract: A die bonding apparatus may include a bond head providing a heating function. The bond head may include a die collet for picking up a semiconductor chip when performing a die bonding process. The die collet may heat the semiconductor chip by using heat transmitted from the bond head when picking up the chip. The die collet may also provide a heating function for heating the chip.

Abstract: Semiconductor packages are provided to prevent a chip, such as a central processing unit (CPU) chip, from being degraded due to hot spot heat generated during the operation of the chip and absorbs thermomechanical stresses in interfaces between the chip, a thermal interface material (TIM) and a lid. The chip is electrically connected, e.g., flip-chip bonded, to a package substrate. The lid is thermally connected to and disposed over a back surface of the chip with the TIM interposed therebetween. A heat dissipation means adjacent the TIM is also located between the lid and the chip to prevent the hot spot effect.

Abstract: A semiconductor wafer includes a plurality of passive device units, which are electrically connected across scribe lines. Passive device chips in the wafer that are adjacent to one another in a first direction are electrically connected in parallel, while passive device units adjacent to one another in a second direction are connected in series. By selecting a number of adjacent passive device units extending in the first and second direction, and separating the selected units from the wafer along the corresponding scribe lines, a passive device chip having a desired electrical characteristic (e.g., capacitance or resistance) can be obtained. Such passive device chips may be assembled in a semiconductor package where they are electrically connected to active devices.

Abstract: A high-power BGA includes a printed circuit board with a through hole, connection pads formed on the bottom of the printed circuit board, matrix solder balls surrounding the through hole and adjacent to the connection pads, a heat spreader on the top surface of the printed circuit board that includes an insulating layer of a high thermal conductivity, a semiconductor chip mounted within the through hole on the bottom surface of the heat spreader that includes a number of contact pads for bonding with the connection pads using gold wires, and a passive film filling the through hole and around the semiconductor chip. By interposing a ceramic insulating layer between the semiconductor chip and the heat spreader, charge generation between the semiconductor chip and the heat spreader is sharply reduced, and defects such as ESD (electrostatic discharge) is reduced during testing and mounting of the package.