Patent application number | Description | Published |
20080258306 | Semiconductor Device and Method for Fabricating the Same - The present invention provides a semiconductor device and a method for fabricating the same. The semiconductor device includes a chip having an active surface and an opposing non-active surface, wherein a plurality of bond pads are formed on the active surface, and first metal layers are formed on the bond pads and to edges of the non-active surface; conductive traces disposed on the non-active surface of the chip; a dielectric layer covering sides of the chip and formed with a plurality of openings therein to expose a portion of the conductive traces; and a plurality of second metal layers formed in the openings of the dielectric layer and on the first metal layers, such that the bond pads are electrically connected to the conductive traces via the first and second metal layers. | 10-23-2008 |
20080265385 | Semiconductor package using copper wires and wire bonding method for the same - A semiconductor package using copper wires and a wire bonding method for the same are proposed. The package includes a carrier having fingers and a chip mounted on the carrier. The method includes implanting stud bumps on the fingers of the carrier and electrically connecting the chip and the carrier by copper wires with one ends of the copper wires being bonded to bond pads of the chip and the other ends of the copper wires being bonded to the stud bumps on the carrier. The implanted stud bumps on the carrier improve bondability of the copper wires to the carrier and thus prevent stitch lift. With good bonding, residues of copper wires left behind after a bonding process have even tail ends and uniform tail length to enable fabrication of solder balls of uniform size, thereby eliminating a conventional step of implanting stud bumps on the bond pads of chips and preventing ball lift from occurring. | 10-30-2008 |
20080277777 | Heat dissipation semiconductor package - A heat dissipation semiconductor package includes a chip carrier, a semiconductor chip, a heat conductive adhesive, a heat dissipation member, and an encapsulant. The semiconductor chip is flip-chip mounted on the chip carrier and defined with a heat conductive adhesive mounting area. Periphery of the heat adhesive mounting area is spaced apart from edge of the semiconductor chip. The heat dissipation member is mounted on the heat conductive adhesive formed in the heat conductive adhesive mounting area. The encapsulant formed between the chip carrier and the heat dissipation member encapsulates the semiconductor chip and the heat conductive adhesive, and embeds edges of the active surface and non-active surface and side edge of the semiconductor chip, thereby increasing bonding area between the encapsulant and the semiconductor chip. The side edges of the heat conductive adhesive and the semiconductor chip are not flush with each other, thereby preventing propagation of delamination. | 11-13-2008 |
20080277786 | Semiconductor package substrate - A semiconductor package substrate includes a body having an upper surface and a lower surface opposite to one another, a plurality of circuit layers formed in the body, a plurality of solder pads formed on the upper surface of the body, and a plurality of solder ball pads formed on the lower surface of the body. Each of the solder pads is electrically connected to one of the solder ball pads via the circuit layers and conductive structures disposed between the circuit layers, wherein the circuit layers and conductive structures are configured to expand outwardly in a fan-out manner so as to provide more space between the circuit layers closer to the lower surface of the body such that part of the solder pad-solder ball pad electrical connections can comprise a plurality of parallel connected conductive structures formed in the space, thereby enhancing the heat conducting passageway and the effect of heat-dissipation without having to dispose more solder pads on surface of the substrate. | 11-13-2008 |
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 |
20080296716 | Sensor semiconductor device and manufacturing method thereof - A sensor semiconductor device and a manufacturing method thereof are disclosed. The method includes: providing a light-permeable carrier board with a plurality of metallic circuits; electrically connecting the metallic circuits to a plurality of sensor chips through conductive bumps formed on the bond pads of the sensor chips, wherein the sensor chips have been previously subjected to thinning and chip probing; filling a first dielectric layer between the sensor chips to cover the metallic circuits and peripheries of the sensor chips; forming a second dielectric layer on the sensor chips and the first dielectric layer; forming grooves between the sensor chips for exposing the metallic circuits such that a plurality of conductive traces electrically connected to the metallic circuits can be formed on the second dielectric layer; and singulating the sensor chips to form a plurality of sensor semiconductor devices. The present invention overcomes the drawbacks of breakage of trace connection due to a sharp angle formed at joints, poor electrical connection and chip damage due to an alignment error in cutting from the back of the wafer, as well as an increased cost due to multiple sputtering processes for forming traces. | 12-04-2008 |
20080303111 | Sensor package and method for fabricating the same - The invention discloses a sensor package and a method for fabricating the same. The sensor package includes: a substrate with an opening; a sensor chip disposed in the opening and electrically connected to the substrate; an encapsulant filling spacing between the sensor chip and the opening so as to secure the sensor chip to the substrate; and a transparent cover attached to the substrate via an adhesive layer, wherein the adhesive layer covers the sensor chip and bonding wires and is formed with an opening for exposing sensor region of the sensor chip. Securing the sensor chip in the opening of the substrate reduces the height of the sensor package, and meanwhile the process cost is reduced by eliminating the need of formation of conductive bumps on the sensor chip or the transparent cover and eliminating the need of specially designed substrate. | 12-11-2008 |
20080308926 | Heat dissipation package structure and method for fabricating the same - A heat dissipation package structure and method for fabricating the same are disclosed, which includes mounting and electrically connecting a semiconductor chip to a chip carrier through its active surface; mounting a heat dissipation member having a heat dissipation section and a supporting section on the chip carrier such that the semiconductor chip can be received in the space formed by the heat dissipation section and the supporting section, wherein the heat dissipation section has an opening formed corresponding to the semiconductor chip; forming an encapsulant to encapsulate the semiconductor chip and the heat dissipation member; and thinning the encapsulant to remove the encapsulant formed on the semiconductor chip to expose inactive surface of the semiconductor chip and the top surface of the heat dissipation section from the encapsulant. Therefore, the heat dissipation package structure is fabricated through simplified fabrication steps at low cost, and also the problem that the chip is easily damaged in a package molding process of the prior art is overcome. | 12-18-2008 |
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 |
20090146285 | FABRICATION METHOD OF SEMICONDUCTOR PACKAGE - The present invention provides a semiconductor package and a fabrication method thereof. The method includes the steps of: providing a chip carrier module having a plurality of chip carriers, disposing a plurality of electrical connecting points on the chip carriers, performing chip mounting and molding on the chip carrier module to form an encapsulant encapsulating the semiconductor chip, exposing the electrical connecting points from the encapsulant; forming a patterned circuit layer on the encapsulant, electrically connecting the patterned circuit layer to the electrical connecting points, cutting and separating the chip carriers to form a plurality of semiconductor packages each having a circuit layer formed on the encapsulant such that the circuit layer provides extra electrical connecting points and thereby enhances electrical performance of electrical products. During a package stacking process, no package is limited by the design of another package below. | 06-11-2009 |
20100041181 | HEAT DISSIPATING PACKAGE STRUCTURE AND METHOD FOR FABRICATING THE SAME - A heat dissipating package structure includes a chip carrier; a semiconductor chip mounted and electrically connected to the chip carrier; a heat spreader having a first surface, an opposed second surface and a hollow structure, the second surface of the heat spreader being mounted on the chip, wherein the chip is larger in size than the hollow structure such that the chip is partly exposed to the hollow structure; an encapsulant formed between the heat spreader and the chip carrier, for encapsulating the chip, wherein the first surface and sides of the heat spreader are exposed from the encapsulant to dissipate heat produced from the chip; and a plurality of conductive elements disposed on the chip carrier, for electrically connecting the chip to an external device. The present invention also provides a method for fabricating the heat dissipating package structure. | 02-18-2010 |
20100052146 | SEMICONDUCTOR PACKAGE AND FABRICATION METHOD THEREOF - A semiconductor package and a fabrication method are disclosed. The fabrication method includes applying a sacrificial layer on one surface of a metal carrier, applying an insulation layer on the sacrificial layer, and forming through holes in the sacrificial layer and the insulation layer to expose the metal carrier; forming a conductive metallic layer in each through hole; forming a patterned circuit layer on the insulation layer to be electrically connected to the conductive metallic layer; mounting at least a chip on the insulation layer and electrically connecting the chip to the patterned circuit layer; forming an encapsulant to encapsulate the chip and the patterned circuit layer; and removing the metal carrier and the sacrificial layer to expose the insulation layer and conductive metallic layer to allow the conductive metallic layer to protrude from the insulation layer. In the present invention, the distance between the semiconductor package and the external device is increased, and thermal stress caused by difference between the thermal expansion coefficients is reduced, so as to enhance the reliability of the product. | 03-04-2010 |
20100151631 | FABRICATION METHOD OF SEMICONDUCTOR PACKAGE HAVING HEAT DISSIPATION DEVICE - A semiconductor package with a heat dissipating device and a fabrication method of the semiconductor package are provided. A chip is mounted on a substrate. The heat dissipating device is mounted on the chip, and includes an accommodating room, and a first opening and a second opening that communicate with the accommodating room. An encapsulant is formed between the heat dissipating device and the substrate to encapsulate the chip. A cutting process is performed to remove a non-electrical part of structure and expose the first and second openings from the encapsulant. A cooling fluid is received in the accommodating room to absorb and dissipate heat produced by the chip. The heat dissipating device covers the encapsulant and the chip to provide a maximum heat transfer area for the semiconductor package. | 06-17-2010 |
20100233855 | METHOD FOR FABRICATING CHIP SCALE PACKAGE STRUCTURE WITH METAL PADS EXPOSED FROM AN ENCAPSULANT - A chip scale package structure and a method for fabricating the same are disclosed. The method includes forming metal pads on a predetermined part of a carrier; mounting chips on the carrier, each of the chips having a plurality of conductive bumps soldered to the metal pads; forming an encapsulant on the carrier to encapsulate the chips and the conductive bumps; removing the carrier to expose the metal pads and even the metal pads with a surface of the encapsulant; forming on the encapsulant a plurality of first conductive traces electrically connected to the metal pads; applying a solder mask on the first conductive traces, and forming a plurality of openings on the solder mask to expose a predetermined part of the first conductive traces; forming a plurality of conductive elements on the predetermined part; and cutting the encapsulant to form a plurality of chip scale package structures. | 09-16-2010 |
20100267202 | METHOD OF FABRICATING STACKED SEMICONDUCTOR STRUCTURE - A stacked semiconductor structure and fabrication method thereof are provided. The method includes mounting and connecting electrically a semiconductor chip to a first substrate, mounting on the first substrate a plurality of supporting members corresponding in position to a periphery of the semiconductor chip, mounting a second substrate having a first surface partially covered with a tape and a second surface opposite to the first surface on the supporting members via the second surface, connecting electrically the first and second substrates by bonding wires, forming on the first substrate an encapsulant for encapsulating the semiconductor chip, the supporting members, the second substrate, the bonding wires, and the tape with an exposed top surface, and removing the tape to expose the first surface of the second substrate and allow an electronic component to be mounted thereon. The present invention prevents reflow-induced contamination, spares a special mold, and eliminates flash. | 10-21-2010 |
20110070697 | METHOD FOR FABRICATING STACK STRUCTURE OF SEMICONDUCTOR PACKAGES - A stack structure of semiconductor packages and a method for fabricating the stack structure are provided. A plurality of electrical connection pads and dummy pads are formed on a surface of a substrate of an upper semiconductor package and at positions corresponding to those around an encapsulant of a lower semiconductor package. Solder balls are implanted to the electrical connection pads and the dummy pads. The upper semiconductor package is mounted on the lower semiconductor package. The upper semiconductor package is electrically connected to the lower semiconductor package by the solder balls implanted to the electrical connection pads, and the encapsulant of the lower semiconductor package is surrounded and confined by the solder balls implanted to the dummy pads. Thereby, the upper semiconductor package is properly and securely positioned on the lower semiconductor package, without the occurrence of misalignment between the upper and lower semiconductor packages. | 03-24-2011 |
20110287587 | METHOD FOR FABRICATING HEAT DISSIPATION PACKAGE STRUCTURE - A heat dissipation package structure and method for fabricating the same are disclosed, which includes mounting and electrically connecting a semiconductor chip to a chip carrier through its active surface; mounting a heat dissipation member having a heat dissipation section and a supporting section on the chip carrier such that the semiconductor chip can be received in the space formed by the heat dissipation section and the supporting section, wherein the heat dissipation section has an opening formed corresponding to the semiconductor chip; forming an encapsulant to encapsulate the semiconductor chip, and the heat dissipation member; and thinning the encapsulant to remove the encapsulant formed on the semiconductor chip to expose inactive surface of the semiconductor chip and the top surface of the heat dissipation section from the encapsulant. Therefore, the heat dissipation package structure is fabricated through simplified fabrication steps at low cost, and also the problem that the chip is easily damaged in a package molding process of the prior art is overcome. | 11-24-2011 |
20110287588 | METHOD FOR MANUFACTURING HEAT-DISSIPATING SEMICONDUCTOR PACKAGE STRUCTURE - A heat-dissipating semiconductor package structure and a method for manufacturing the same is disclosed. The method includes: disposing on and electrically connecting to a chip carrier at least a semiconductor chip and a package unit; disposing on the top surface of the package unit a heat-dissipating element having a flat portion and a supporting portion via the flat portion; receiving the package unit and semiconductor chip in a receiving space formed by the flat portion and supporting portion of the heat-dissipating element; and forming on the chip carrier encapsulant for encapsulating the package unit, semiconductor chip, and heat-dissipating element. The heat-dissipating element dissipates heat generated by the package unit, provides EMI shielding, prevents delamination between the package unit and the encapsulant, decreases thermal resistance, and prevents cracking. | 11-24-2011 |
20140179067 | FABRICATION METHOD OF SEMICONDUCTOR PACKAGE - A semiconductor package and a fabrication method thereof are disclosed. The fabrication method includes the steps of providing a semiconductor chip having an active surface and a non-active surface opposing to the active surface, roughening a peripheral portion of the non-active surface so as to divide the non-active surface into the peripheral portion formed with a roughened structure and a non-roughened central portion, mounting the semiconductor chip on a chip carrier via a plurality of solder bumps formed on the active surface, forming an encapsulant on the chip carrier to encapsulate the semiconductor chip. The roughened structure formed on the peripheral portion of the non-active surface of the semiconductor chip can reinforce the bonding between the semiconductor chip and the encapsulant, and the non-roughened central portion of the non-active surface of the semiconductor chip can maintain the structural strength of the semiconductor chip. | 06-26-2014 |
20150054150 | SEMICONDUCTOR PACKAGE AND FABRICATION METHOD THEREOF - A method for fabricating a semiconductor package is disclosed, which includes: providing first and second packaging substrates, wherein a surface of the first packaging substrate has first conductive pads and first conductive posts formed on the first conductive pads, a surface of the second packaging substrate has second conductive pads and second conductive posts formed on the second conductive pads, and the surface of the second packaging substrate further has a semiconductor chip disposed thereon; disposing the first packaging substrate on the second packaging substrate in a manner that the first conductive posts correspond in position to and are electrically connected to the second conductive posts; and forming an encapsulant between the first and second packaging substrates for encapsulating the first and second conductive posts and the semiconductor chip, thereby effectively preventing solder bridging and increasing the product yield and reliability. | 02-26-2015 |