Patent application number | Description | Published |
20080224289 | Multi-chip stack structure and fabrication method thereof - A multi-chip stack structure and a fabrication method thereof are proposed, including providing a leadframe having a die base and a plurality of leads and disposing a first and a second chips on the two surfaces of the die base respectively; disposing the leadframe on a heating block having a cavity in a wire bonding process with the second chip received in the cavity of the heating block; performing a first wire bonding process to electrically connect the first chip to the leads through a plurality of first bonding wires, and forming a bump on one side of the leads connected with the first bonding wires; disposing the leadframe in an upside down manner to the heating block via the bump with the first chip and the first bonding wires received in the cavity of the heating block; and performing a second wire bonding process to electrically connect the second chip to the leads through a plurality of second bonding wires. The bump is used for supporting the leads to a certain height so as to keep the bonding wires from contacting the heating block and eliminate the need of using a second heating block in the second wire bonding process of the prior art, thereby saving time and costs in a fabrication process. Also, as positions where the first and second bonding wires are bonded to the leads on opposite sides of the leadframe correspond with each other, the conventional problems of adversely affected electrical performance and electrical mismatch can be prevented. | 09-18-2008 |
20080230913 | Stackable semiconductor device and fabrication method thereof - The invention provides a stackable semiconductor device and a fabrication method thereof, including providing a wafer having a plurality of dies mounted thereon, both the die and the wafer having an active surface and a non-active surface opposing one another respectively, wherein each die has a plurality of solder pads formed on the active surface thereof and a groove formed between adjacent solder pads to form a first metal layer therein that is electrically connected to the solder pads; subsequently thinning the non-active surface of the wafer to where the grooves are located to expose the first metal layer therefrom, and forming a second metal layer on the non-active surface of the wafer for electrically connecting with the first metal layer; and separating the dies to form a plurality of stackable semiconductor devices. Thereby, the first and second metal layers formed on the active surface and the non-active surface of the semiconductor device can be stacked and connected to constitute a multi-die stack structure, thereby increasing integration without increasing the area of the stacked dies. Further, the problems known in the prior art of poor electrical connection, complicated manufacturing process and increased cost as a result of using wire bonding and TSV can be avoided. | 09-25-2008 |
20080251937 | Stackable semiconductor device and manufacturing method thereof - A stackable semiconductor device and a manufacturing method thereof are disclosed. The method includes providing a wafer comprised of a plurality of chips, wherein a plurality of solder pads are formed on the active surface of each chip, and a plurality of grooves are formed between the solder pads of any two adjacent ones of the chips; forming a dielectric layer on regions between the solder pads of any two adjacent ones of the chips ; forming a metal layer on the dielectric layer electrically connected to the solder pads and forming a connective layer on the metal layer, wherein the width of the connective layer is smaller than that of the metal layer; cutting along the grooves to break off the electrical connection between adjacent chips; thinning the non-active surface of the wafer to the extent that the metal layer is exposed from the wafer; and separating the chips to form a plurality of stackable semiconductor devices. Accordingly, a multi-chip stack structure can be obtained by stacking and electrically connecting a plurality of semiconductor devices through the electrical connection between the connective layer of a semiconductor device and the metal layer of another semiconductor device, thereby effectively integrating more chips without having to increase the stacking area, and further the problems of poor electrical connection, complicated manufacturing processes and high costs known in the prior art can be avoided. | 10-16-2008 |
20080283982 | Multi-chip semiconductor device having leads and method for fabricating the same - The present invention proposes a multi-chip semiconductor device having leads and a method for fabricating the same. The method includes the steps of: providing a substrate having a plurality of connection pads disposed on a surface thereof; mounting a plurality of semiconductor chips on the surface of the substrate, and electrically connecting the semiconductor chips to the surface of the substrate; forming an encapsulant on the substrate to encapsulate the semiconductor chips and expose the connection pads to form a package unit; and providing a lead frame having a plurality of leads, and electrically connecting the connection pads exposed from the package unit to the leads of the lead frame to form a multi-chip semiconductor device having leads, thereby forming a multi-chip semiconductor device having leads. By the multi-chip semiconductor device and the method for fabricating the same as proposed in the present invention, problems like poor reliability caused by stress induced by several types of materials in a semiconductor package into which a substrate and leads are integrated, moisture absorption by an encapsulated substrate, and cracks developed as a result of moisture absorption by the substrate can be avoided. | 11-20-2008 |
20080283994 | Stacked package structure and fabrication method thereof - A stacked package structure and fabrication method thereof are disclosed, including providing a substrate having a plurality of stackable solder pads formed on surface thereof for allowing at least one semiconductor chip to be electrically connected to the substrate; forming an encapsulant for encapsulating the semiconductor chip and further exposing the stackable solder pads from the encapsulant, thus forming a lower-layer semiconductor package; forming conductive bumps on at least one stackable solder pad by means of wire bonding such that at least one upper-layer semiconductor package can be mounted via solder balls on the conductive bumps and the stackable solder pads of the lower-layer semiconductor package to form a stacked package structure, wherein, stacking height of the solder balls and the conductive bumps is greater than height of the encapsulant of the lower-layer semiconductor package, thus, when stacking fine pitch semiconductor packages or when warps occur to the upper-layer semiconductor package or the lower-layer semiconductor package, the conductive bumps can compensate for inadequate height caused by solder ball collapse or fill up gaps between the solder balls and the stackable solder pads caused by warps, thereby allowing the solder balls to be able to effectively contact and wet on the substrate of the lower-layer semiconductor package. | 11-20-2008 |
20080303134 | Semiconductor package and method for fabricating the same - A semiconductor package and a method for fabricating the same are disclosed, which includes: providing a carrier board, forming a plurality of metal bumps on the carrier board, forming a metal layer on the carrier board to encapsulate the metal bumps, having at least one semiconductor chip electrically connected to the metal layer, then forming an encapsulant on the carrier board to encapsulate the semiconductor chip, and next removing the carrier board and the metal bumps to correspondingly form a plurality of grooves on surface of the encapsulant, wherein bottom and sides of the grooves are covered with the metal layer to allow electroconductive components to be effectively positioned in the grooves and completely bonded with the metal layer. | 12-11-2008 |
20090014860 | Multi-chip stack structure and fabricating method thereof - A multi-chip stack structure and a manufacturing method thereof are provided. The fabrication method includes the steps of: providing a chip carrier having a first surface and a second surface opposing thereto and at least a first chip and a second chip mounted on the first surface; electrically connecting the chips to the chip carrier by a plurality of bonding wires; and stacking at least a third chip on the first and second chips by a film deposed therebetween, wherein the third chip is stepwise stacked on the first chip and at least a part of the bonding wire connected to the second chip is covered by the film, and electrically connecting the third chip and the chip carrier by a bonding wire, thereby enabling a plurality of chips to be stacked on the chip carrier to enhance the electrical performance of electronic products. | 01-15-2009 |
20090032928 | Multi-chip stack structure having through silicon via and method for fabrication the same - The invention discloses a multi-chip stack structure having through silicon via and a method for fabricating the same. The method includes: providing a wafer having a plurality of first chips; forming a plurality of holes on a first surface of each of the first chips and forming metal posts and solder pads corresponding to the holes so as to form a through silicon via (TSV) structure; forming at least one groove on a second surface of each of the first chips to expose the metal posts of the TSV structure so as to allow at least one second chip to be stacked on the first chip, received in the groove and electrically connected to the metal posts exposed from the groove; filling the groove with an insulating material for encapsulating the second chip; mounting conductive elements on the solder pads of the first surface of each of the first chips and singulating the wafer; and mounting and electrically connecting the stacked first and second chips to a chip carrier via the conductive elements. The wafer, which is not totally thinned but includes a plurality of first chips, severs a carrying purpose during the fabrication process and thereby solves problems, namely a complicated process, high cost, and adhesive layer contamination, facing the prior art that entails repeated use of a carrier board and an adhesive layer for vertically stacking a plurality of chips and mounting the stacked chips on a chip carrier. | 02-05-2009 |
20090057799 | Sensor semiconductor device and method for fabricating the same - A sensor semiconductor device and a method for fabricating the same are provided. At least one sensor chip is mounted and electrically connected to a lead frame. A first and a second encapsulation molding processes are sequentially performed to form a transparent encapsulant for encapsulating the sensor chip and a part of the lead frame and to form a light-impervious encapsulant for encapsulating the transparent encapsulant. The transparent encapsulant has a light-pervious portion formed at a position corresponding to and above a sensor zone of the sensor chip. The light-pervious portion is exposed from the light-impervious encapsulant. Light may penetrate the light-pervious portion, without using an additional cover board, thereby reducing manufacturing steps and costs. The above arrangement avoids prior-art problems of poor reliability caused by a porous encapsulant and poor signal reception caused by interference of ambient light entering into a conventional chip only encapsulated by a transparent encapsulant. | 03-05-2009 |
20090140440 | MULTI-CHIP STACK STRUCTURE AND METHOD FOR FABRICATING THE SAME - A multi-chip stack structure and a method for fabricating the same are provided. The method for fabricating a multi-chip stack structure includes disposing a first chip group comprising a plurality of first chips on a chip carrier by using a step-like manner, disposing a second chip on the first chip on top of the first chip group, electrically connecting the first chip group and the second chip to the chip carrier through bonding wires, using film over wire (FOW) to stack a third chip on the first and the second chips with an insulative film provided therebetween, wherein the insulative film covers part of the ends of the bonding wires of the first chip on the top of the first group and at least part of the second chip, and electrically connecting the third chip to the chip carrier through bonding wires, thereby preventing directly disposing on a first chip a second chip having a planar size far smaller than that of the first chip as in the prior art that increases height of the entire structure and increases the wiring bonding difficulty. | 06-04-2009 |
20090166831 | SENSOR SEMICONDUCTOR PACKAGE AND METHOD FOR FABRICATING THE SAME - This invention provides a sensor semiconductor package and a method for fabricating the same. The method includes: mounting on a substrate a sensor chip having a sensor area; electrically connecting the sensor chip and the substrate by means of bonding wires; forming on a transparent member an adhesive layer with an opening corresponding in position to the sensor area; and mounting the transparent member on the substrate via the adhesive layer while heating the substrate, such that the adhesive layer melts, to thereby encapsulate the periphery of the sensor chip and the bonding wires while exposing the sensor area from the adhesive layer. Thus, the sensor area is sealed by the transparent member cooperative with the adhesive layer, making the sensor semiconductor package thus-obtained dam-free, light, thin, and compact, and incurs low process costs. Also, the product reliability is enhanced since the bonding wires are encapsulated by the adhesive layer without severing concern. | 07-02-2009 |
20090261476 | Semiconductor device and manufacturing method thereof - A semiconductor device and a manufacturing method thereof are disclosed. The method includes the steps of providing a carrier board having conductive circuits disposed thereon and a plurality of chips with active surfaces having solder pads disposed thereon, wherein conductive bumps are disposed on the solder pads; mounting chips on the carrier board; filling the spacing between the chips with a dielectric layer and forming openings in the dielectric layer at periphery of each chip to expose the conductive circuits; forming a metal layer in the openings of the dielectric layer and at periphery of the active surface of the chips for electrically connecting the conductive bumps and the conductive circuits; and cutting along the dielectric layer between the chips and removing the carrier board to separate each chip and exposing the conductive circuits from the non-active surface. | 10-22-2009 |
20090294959 | Semiconductor package device, semiconductor package structure, and fabrication methods thereof - A semiconductor package device, a semiconductor package structure, and fabrication methods thereof are provided, which mainly includes disposing a plurality of semiconductor chips on a wafer formed with TSVs (Through Silicon Vias) and electrically connecting the semiconductor chips to the TSVs; encapsulating the semiconductor chips with an encapsulant; and disposing a hard component on the encapsulant. The hard component ensures flatness of the wafer during a solder bump process and provides support to the wafer during a singulation process such that the wafer can firmly lie on a singulation carrier, thereby overcoming the drawbacks of the prior art, namely difficulty in mounting of solder bumps, and difficulty in cutting of the wafer. | 12-03-2009 |