Patent application number | Description | Published |
20100297842 | CONDUCTIVE BUMP STRUCTURE FOR SEMICONDUCTOR DEVICE AND FABRICATION METHOD THEREOF - A conductive bump structure for a semiconductor device and a method for fabricating the same are provided. A metal bump is formed on an under bump metallurgy (UBM) structure electrically connected to and formed on a connection pad of the semiconductor device, wherein the metal bump is sized smaller than the UBM structure. Subsequently, a solder bump is mounted on the UBM structure and encapsulates the metal bump, so as to increase the bonding area and simultaneously allow the solder bump to be sufficiently wetted on the UBM structure to enhance bonding stress of the solder bump. | 11-25-2010 |
20100323513 | FABRICATION METHOD OF SEMICONDUCTOR DEVICE HAVING CONDUCTIVE BUMPS - A semiconductor device having conductive bumps and a fabrication method thereof are provided. The fabrication method mainly including steps of: providing a semiconductor substrate having a solder pad and a passivation layer formed thereon with a portion of the solder pads exposed from the passivation layer; disposing a first metal layer on the solder pad and a portion of the passivation layer around the solder pad; disposing a covering layer on the first metal layer and the passivation layer, and forming an aperture in the covering layer to expose a portion of the first metal layer, wherein a center of the aperture is deviated from that of the solder pad; deposing a metal pillar on the portion of the first metal layer; and deposing a solder material on an outer surface of the metal pillar for providing a better buffering effect. | 12-23-2010 |
20110070728 | FABRICATION METHOD OF SEMICONDUCTOR DEVICE HAVING CONDUCTIVE BUMPS - A semiconductor device having conductive bumps and a fabrication method thereof is proposed. The fabrication method includes the steps of forming a first metallic layer on a substrate having solder pads and a passivation layer formed thereon, and electrically connecting it to the solder pads; applying a second covering layer over exposed parts of the first metallic layer; subsequently, forming a second metallic layer on the second covering layer, and electrically connecting it to the exposed parts of the first metallic layer; applying a third covering layer, and forming openings for exposing parts of the second metallic layer to form thereon a conductive bump having a metallic standoff and a solder material. The covering layers and the metallic layers can provide a buffering effect for effectively absorbing the thermal stress imposed on the conductive bumps to prevent delamination caused by the UBM layers. | 03-24-2011 |
20110156227 | SEMICONDUCTOR PACKAGE STRUCTURE - A semiconductor package structure includes: a dielectric layer; a metal layer disposed on the dielectric layer and having a die pad and traces, the traces each including a trace body, a bond pad extending to the periphery of the die pad, and an opposite trace end; metal pillars penetrating the dielectric layer with one ends thereof connecting to the die pad and the trace ends while the other ends thereof protruding from the dielectric layer; a semiconductor chip mounted on the die pad and electrically connected to the bond pads through bonding wires; and an encapsulant covering the semiconductor chip, the bonding wires, the metal layer, and the dielectric layer. The invention is characterized by disposing traces with bond pads close to the die pad to shorten bonding wires and forming metal pillars protruding from the dielectric layer to avoid solder bridging encountered in prior techniques. | 06-30-2011 |
20110156252 | SEMICONDUCTOR PACKAGE HAVING ELECTRICAL CONNECTING STRUCTURES AND FABRICATION METHOD THEREOF - A semiconductor package having electrical connecting structures includes: a conductive layer having a die pad and traces surrounding the die pad; a chip; bonding wires; an encapsulant with a plurality of cavities having a depth greater than the thickness of the die pad and traces for embedding the die pad and the traces therein, and the cavities exposing the die pad and the traces; a solder mask layer formed in the cavities and having a plurality of openings for exposing the trace ends and a portion of the die pad; and solder balls formed in the openings and electrically connected to the trace ends. Engaging the solder mask layer with the encapsulant enhances adhesion strength of the solder mask layer so as to prolong the moisture permeation path and enhance package reliability. | 06-30-2011 |
20110159643 | FABRICATION METHOD OF SEMICONDUCTOR PACKAGE STRUCTURE - A fabrication method of a semiconductor package structure includes: patterning a metal plate having first and second surfaces; forming a dielectric layer on the metal plate; forming a metal layer on the first surface and the dielectric layer; forming metal pads on the second surface, the metal layer having a die pad and traces each having a bond pad; mounting a semiconductor chip on the die pad, followed by connecting electrically the semiconductor chip to the bond pads through bonding wires; forming an encapsulant to cover the semiconductor chip and the metal layer; removing portions of the metal plate not covered by the metal pads so as to form metal pillars; and performing a singulation process. The fabrication method is characterized by disposing traces with bond pads close to the die pad to shorten the bonding wires and forming metal pillars protruding from the dielectric layer to avoid solder bridging. | 06-30-2011 |
20110175179 | PACKAGE STRUCTURE HAVING MEMS ELEMENT - A package structure having at least an MEMS element is provided, including a chip having electrical connecting pads and the MEMS element; a lid disposed on the chip to cover the MEMS element and having a metal layer provided thereon; first sub-bonding wires electrically connecting to the electrical connecting pads; second sub-bonding wires electrically connecting to the metal layer; an encapsulant disposed on the chip, wherein the top ends of the first and second sub-bonding wires are exposed from the encapsulant; and metallic traces disposed on the encapsulant and electrically connecting to the first sub-bonding wires. The package structure advantageously features reduced size, relatively low costs, diverse bump locations, and an enhanced EMI shielding effect. | 07-21-2011 |
20110175210 | EMI SHIELDING PACKAGE STRUCTURE AND METHOD FOR FABRICATING THE SAME - An EMI shielding package structure includes a substrate unit having a first surface with a die mounting area and a second surfaces opposite to the first surface, metallic pillars formed on the first surface, a chip mounted on and electrically connected to the die-mounting area, an encapsulant covering the chip and the first surface while exposing a portion of each of the metallic pillars from the encapsulant, and a shielding film enclosing the encapsulant and electrically connecting to the metallic pillars. A fabrication method of the above structure by two cutting processes is further provided. The first cutting process forms grooves by cutting the encapsulant. After a shielding film is formed in the grooves and electrically connected to the metallic pillars, the complete package structure is formed by the second cutting process, thereby simplifying the fabrication process while overcoming inferior grounding of the shielding film as encountered in prior techniques. | 07-21-2011 |
20110177643 | FABRICATION METHOD OF PACKAGE STRUCTURE HAVING MEMS ELEMENT - A fabrication method of a package structure having at least an MEMS element is provided, including: preparing a wafer having electrical connection pads and the at least an MEMS element; disposing lids for covering the at least an MEMS element, the lids having a metal layer formed thereon; electrically connecting the electrical connection pads and the metal layer with bonding wires; forming an encapsulant for covering the lids, bonding wires, electrical connection pads and metal layer; removing portions of the encapsulant to separate the bonding wires each into first and second sub-bonding wires, wherein top ends of the first and second sub-bonding wires are exposed, the first sub-bonding wires electrically connecting to the electrical connection pads, and the second sub-bonding wires electrically connecting to the metal layer; forming metallic traces on the encapsulant for electrically connecting to the first sub-bonding wires; forming bumps on the metallic traces; and performing a singulation process. | 07-21-2011 |
20110198737 | QUAD FLAT NON-LEADED PACKAGE STRUCTURE WITH ELECTROMAGNETIC INTERFERENCE SHIELDING FUNCTION AND METHOD FOR FABRICATING THE SAME - A quad flat non-leaded (QFN) package structure with an electromagnetic interference (EMI) shielding function is proposed, including: a lead frame having a die pad, a plurality of supporting portions connecting to the die pad and a plurality of leads disposed around the periphery of the die pad without connecting to the die pad; a chip mounted on the die pad; bonding wires electrically connecting the chip and the leads; an encapsulant for encapsulating the chip, the bonding wires and the lead frame and exposing the side and bottom surfaces of the leads and the bottom surface of the die pad; and a shielding film disposed on the top and side surfaces of the encapsulant and electrically connecting to the supporting portions for shielding from EMI. A method of fabricating the package structure as described above is further proposed. | 08-18-2011 |
20110298126 | CARRIER-FREE SEMICONDUCTOR PACKAGE AND FABRICATION METHOD - A method for fabricating a carrier-free semiconductor package includes: half-etching a metal carrier to form a plurality of recess grooves and a plurality of metal studs each serving in position as a solder pad or a die pad; filing each of the recess grooves with a first encapsulant; forming on the metal studs an antioxidant layer such as a silver plating layer or an organic solderable protection layer; and performing die-bonding, wire-bonding and molding processes respectively to form a second encapsulant encapsulating the chip. The recess grooves are filled with the first encapsulant to enhance the adhesion between the first encapsulant and the metal carrier, thereby solving the conventional problem of having a weak and pliable copper plate and avoiding transportation difficulty. The invention eliminates the use of costly metals as an etching resist layer to reduce fabrication cost, and further allows conductive traces to be flexibly disposed on the metal carrier to enhance electrical connection quality. | 12-08-2011 |
20120007234 | SEMICONDUCTOR PACKAGE WITHOUT CHIP CARRIER AND FABRICATION METHOD THEREOF - A semiconductor package without a chip carrier formed thereon and a fabrication method thereof. A metallic carrier is half-etched to form a plurality of grooves and metal studs corresponding to the grooves. The grooves are filled with a first encapsulant and a plurality of bonding pads are formed on the metal studs. The first encapsulant is bonded with the metal studs directly. Each of the bonding pads and one of the metal studs corresponding to the bonding pad form a T-shaped structure. Therefore, bonding force between the metal studs and the first encapsulant is enhanced such that delamination is avoided. Die mounting, wire-bonding and molding processes are performed subsequently. Since the half-etched grooves are filled with the first encapsulant, the drawback of having pliable metallic carrier that makes transportation difficult to carry out as encountered in prior techniques is overcome, and the manufacturing cost is educed by not requiring the use of costly metals as an etching resist layer. | 01-12-2012 |
20120013006 | CHIP SCALE PACKAGE AND FABRICATION METHOD THEREOF - A fabrication method of a chip scale package is provided, which includes forming a protection layer on the active surface of a chip and fixing the inactive surface of the chip to a transparent carrier; performing a molding process; removing the protection layer from the chip and performing a redistribution layer (RDL) process, thereby solving the conventional problems caused by directly attaching the chip on an adhesive film, such as film-softening caused by heat, encapsulant overflow, warpage, chip deviation and contamination that lead to poor electrical connection between the wiring layer formed in the RDL process and the chip electrode pads and even waste product as a result. Further, the transparent carrier employed in the invention can be separated by laser and repetitively used in the process to help reduce the fabrication cost. | 01-19-2012 |
20120032347 | CHIP SCALE PACKAGE AND FABRICATION METHOD THEREOF - A fabrication method of a chip scale package includes providing electronic components, each having an active surface with electrode pads and an opposite inactive surface, and a hard board with a soft layer disposed thereon; adhering the electronic components to the soft layer via the inactive surfaces thereof; pressing the electronic components such that the soft layer encapsulates the electronic components while exposing the active surfaces thereof; forming a dielectric layer on the active surfaces of the electronic components and the soft layer; and forming a first wiring layer on the dielectric layer and electrically connected to the electrode pads, thereby solving the conventional problems caused by directly attaching a chip on an adhesive film, such as film-softening, encapsulant overflow, warpage, chip deviation and contamination that lead to poor electrical connection between the electrode pads and the wiring layer formed in a subsequent RDL process and even waste product. | 02-09-2012 |
20120038044 | CHIP SCALE PACKAGE AND FABRICATION METHOD THEREOF - A CSP includes: a hard board having a first wiring layer with conductive pads; a plurality of conductive elements disposed on at least a portion of the conductive pads; an electronic component having opposite active and inactive surfaces and being mounted on the hard board via the inactive surface; an encapsulating layer disposed on the hard board for encapsulating the conductive elements and electronic component, the active surface of the electronic component and the surfaces of the conductive elements being exposed through the encapsulating layer; a first dielectric layer and a third wiring layer disposed on the encapsulating layer, the third wiring layer being electrically connected to the conductive elements and the electronic component and further electrically connected to the first wiring layer through the conductive elements, thereby obtaining a stacked connection structure without the need of PTHs and using the hard board as a main structure to avoid warpage. | 02-16-2012 |
20120061825 | CHIP SCALE PACKAGE AND METHOD OF FABRICATING THE SAME - A chip scale package and a method of fabricating the chip scale package. The chip scale package includes a encapsulant having a first surface and a second surface opposing the first surface; a conductive pillar formed in the encapsulant and exposed from the first surface and the second surface; a chip embedded in the encapsulant while exposed from the first surface; a dielectric layer formed on the first surface, the conductive pillar and the chip; a circuit layer formed on the dielectric layer; a plurality of conductive blind vias formed in the dielectric layer electrically connecting the circuit layer, electrode pads and the conductive pillar; and a solder mask layer formed on the dielectric layer and the circuit layer, thereby using conductive pillars to externally connect with other electronic devices as required to form a stacked structure. | 03-15-2012 |
20120241937 | PACKAGE STRUCTURE HAVING MICRO-ELECTROMECHANICAL ELEMENT - Proposed is a package structure having a micro-electromechanical (MEMS) element, including a chip having a plurality of electrical connecting pads and a MEMS element formed thereon; a lid disposed on the chip for covering the MEMS element; a stud bump disposed on each of the electrical connecting pads; an encapsulant formed on the chip with part of the stud bumps being exposed from the encapsulant; and a metal conductive layer formed on the encapsulant and connected to the stud bumps. The invention is characterized by completing the packaging process on the wafer directly to enable thinner and cheaper package structures to be fabricated within less time. This invention further provides a method for fabricating the package structure as described above. | 09-27-2012 |
20120286425 | PACKAGE HAVING MEMS ELEMENT AND FABRICATION METHOD THEREOF - A package structure having an MEMS element is provided, which includes: a protection layer having openings formed therein; conductors formed in the openings, respectively; conductive pads formed on the protection layer and the conductors; a MEMS chip disposed on the conductive pads; and an encapsulant formed on the protection layer for encapsulating the MEMS chip. By disposing the MEMS chip directly on the protection layer to dispense with the need for a carrier, such as a wafer or a circuit board that would undesirably add to the thickness, the present invention reduces the overall thickness of the package to thereby achieve miniaturization. | 11-15-2012 |
20130161802 | SEMICONDUCTOR PACKAGE HAVING ELECTRICAL CONNECTING STRUCTURES AND FABRICATION METHOD THEREOF - A semiconductor package having electrical connecting structures includes: a conductive layer having a die pad and traces surrounding the die pad; a chip; bonding wires; an encapsulant with a plurality of cavities having a depth greater than the thickness of the die pad and traces for embedding the die pad and the traces therein, and the cavities exposing the die pad and the traces; a solder mask layer formed in the cavities and having a plurality of openings for exposing the trace ends and a portion of the die pad; and solder balls formed in the openings and electrically connected to the trace ends. Engaging the solder mask layer with the encapsulant enhances adhesion strength of the solder mask layer so as to prolong the moisture permeation path and enhance package reliability. | 06-27-2013 |
20130200508 | SEMICONDUCTOR PACKAGE STRUCTURE - A semiconductor package structure includes: a dielectric layer; a metal layer disposed on the dielectric layer and having a die pad and traces, the traces each including a trace body, a bond pad extending to the periphery of the die pad, and an opposite trace end; metal pillars penetrating the dielectric layer with one ends thereof connecting to the die pad and the trace ends while the other ends thereof protruding from the dielectric layer; a semiconductor chip mounted on the die pad and electrically connected to the bond pads through bonding wires; and an encapsulant covering the semiconductor chip, the bonding wires, the metal layer, and the dielectric layer. The invention is characterized by disposing traces with bond pads close to the die pad to shorten bonding wires and forming metal pillars protruding from the dielectric layer to avoid solder bridging encountered in prior techniques. | 08-08-2013 |
20130203200 | FABRICATION METHOD OF PACKAGE STRUCTURE HAVING MEMS ELEMENT - A fabrication method of a package structure having at least an MEMS element is provided, including: preparing a wafer having electrical connection pads and the at least an MEMS element; disposing lids for covering the at least an MEMS element, the lids having a metal layer formed thereon; electrically connecting the electrical connection pads and the metal layer with bonding wires; forming an encapsulant for covering the lids, bonding wires, electrical connection pads and metal layer; removing portions of the encapsulant to separate the bonding wires each into first and second sub-bonding wires, wherein top ends of the first and second sub-bonding wires are exposed, the first sub-bonding wires electrically connecting to the electrical connection pads, and the second sub-bonding wires electrically connecting to the metal layer; forming metallic traces on the encapsulant for electrically connecting to the first sub-bonding wires; forming bumps on the metallic traces; and performing a singulation process. | 08-08-2013 |
20140191376 | SEMICONDUCTOR PACKAGE AND FABRICATION METHOD THEREOF - A semiconductor package is provided, including: a substrate; a first semiconductor element disposed on the substrate and having a first conductive pad grounded to the substrate; a conductive layer formed on the first semiconductor element and electrically connected to the substrate; a second semiconductor element disposed on the first semiconductor element through the conductive layer; and an encapsulant formed on the substrate and encapsulating the first and second semiconductor elements. Therefore, the first and second semiconductor elements are protected from electromagnetic interference (EMI) shielding with the conductive layer being connected to the grounding pad of the substrate. A fabrication method of the semiconductor package is also provided. | 07-10-2014 |
20140206146 | FABRICATION METHOD OF SEMICONDUCTOR PACKAGE HAVING ELECTRICAL CONNECTING STRUCTURES - A semiconductor package having electrical connecting structures includes: a conductive layer having a die pad and traces surrounding the die pad; a chip; bonding wires; an encapsulant with a plurality of cavities having a depth greater than the thickness of the die pad and traces for embedding the die pad and the traces therein, and the cavities exposing the die pad and the traces; a solder mask layer formed in the cavities and having a plurality of openings for exposing the trace ends and a portion of the die pad; and solder balls formed in the openings and electrically connected to the trace ends. Engaging the solder mask layer with the encapsulant enhances adhesion strength of the solder mask layer so as to prolong the moisture permeation path and enhance package reliability. | 07-24-2014 |
20140315351 | FABRICATION METHOD OF SEMICONDUCTOR PACKAGE WITHOUT CHIP CARRIER - A semiconductor package without a chip carrier formed thereon and a fabrication method thereof. A metallic carrier is half-etched to form a plurality of grooves and metal studs corresponding to the grooves. The grooves are filled with a first encapsulant and a plurality of bonding pads are formed on the metal studs. The first encapsulant is bonded with the metal studs directly. Each of the bonding pads and one of the metal studs corresponding to the bonding pad form a T-shaped structure. Therefore, bonding force between the metal studs and the first encapsulant is enhanced such that delamination is avoided. Die mounting, wire-bonding and molding processes are performed subsequently. Since the half-etched grooves are filled with the first encapsulant, the drawback of having pliable metallic carrier that makes transportation difficult to carry out as encountered in prior techniques is overcome, and the manufacturing cost is educed by not requiring the use of costly metals as an etching resist layer. | 10-23-2014 |
20150035163 | SEMICONDUCTOR PACKAGE AND METHOD OF FABRICATING THE SAME - The present invention provides a semiconductor package and a method of fabricating the same, including: placing a semiconductor element in a groove of a carrier; forming a dielectric layer on the semiconductor element; forming on the dielectric layer a circuit layer electrically connected to the semiconductor element; and removing a first portion of the carrier below the groove to keep a second of the carrier on a sidewall of the groove intact for the second portion to function as a supporting part. The present invention does not require formation of a silicon interposer, therefore the overall cost of the final product is much reduced. | 02-05-2015 |
20150035164 | SEMICONDUCTOR PACKAGE AND METHOD OF FABRICATING THE SAME - The present invention provides a semiconductor package and a method of fabricating the same, including: placing in a groove of a carrier a semiconductor element having opposing active and non-active surfaces, and side surfaces abutting the active surface and the non-active surface; applying an adhesive material in the groove and around a periphery of the side surfaces of the semiconductor element; forming a dielectric layer on the adhesive material and the active surface of the semiconductor element; forming on the dielectric layer a circuit layer electrically connected to the semiconductor element; and removing a first portion of the carrier below the groove to keep a second portion of the carrier on a side wall of the groove intact for the second portion to function as a supporting member. The present invention does not require formation of a silicon interposer, and therefore the overall cost of a final product is much reduced. | 02-05-2015 |
Patent application number | Description | Published |
20080211093 | Semiconductor device having conductive bumps and fabrication method thereof - A semiconductor device having conductive bumps and a fabrication method thereof is proposed. The fabrication method includes the steps of forming a first metallic layer on a substrate having solder pads and a passivation layer formed thereon, and electrically connecting it to the solder pads; applying a second covering layer over exposed parts of the first metallic layer; subsequently, forming a second metallic layer on the second covering layer, and electrically connecting it to the exposed parts of the first metallic layer; applying a third covering layer, and forming openings for exposing parts of the second metallic layer to form thereon a conductive bump having a metallic standoff and a solder material. The covering layers and the metallic layers can provide a buffering effect for effectively absorbing the thermal stress imposed on the conductive bumps to prevent delamination caused by the UBM layers. | 09-04-2008 |
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 |
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 |
20090008801 | Semiconductor device and method for fabricating the same - This invention discloses a semiconductor device and a method for fabricating the same. The method includes providing a flexible carrier board having a first surface and a second surface opposite thereto; forming a metal lead layer and a first heat dissipating metal layer on the first surface of the flexible carrier board, and forming a second heat dissipating metal layer on the second surface of the flexible carrier board; providing a chip having an active surface and an opposed non-active surface, wherein a plurality of solder pads are formed on the active surface of the chip, each of the solder pads has a metal bump formed thereon and corresponding in position to the metal lead layer, and heat dissipating bumps are formed between the metal bumps corresponding in position to the first heat dissipating metal layer. | 01-08-2009 |
20090102063 | Semiconductor package and method for fabricating the same - This invention provides a semiconductor package and a method for fabricating the same. The method includes: forming a first resist layer on a metal carrier; forming a plurality of openings penetrating the first resist layer; forming a conductive metal layer in the openings; removing the first resist layer; covering the metal carrier having the conductive metal layer with a dielectric layer; forming blind vias in the dielectric layer to expose a portion of the conductive metal layer; forming conductive circuit on the dielectric layer and conductive posts in the blind vias, such that the conductive circuit is electrically connected to the conductive metal layer via the conductive posts; electrically connecting at least one chip to the conductive circuit; forming an encapsulant for encapsulating the chip and the conductive circuit; and removing the metal carrier, thereby allowing a semiconductor package to be formed without a chip carrier. Given the conductive posts, both the conductive circuit and conductive metal layer are efficiently coupled to the dielectric layer to prevent delamination. Further, downsizing the blind vias facilitates the fabrication process and cuts the fabrication cost. | 04-23-2009 |
20110156180 | PACKAGE STRUCTURE HAVING MICRO-ELECTROMECHANICAL ELEMENT AND FABRICATION METHOD THEREOF - Proposed is a package structure having a micro-electromechanical (MEMS) element, including a chip having a plurality of electrical connecting pads and a MEMS element formed thereon; a lid disposed on the chip for covering the MEMS element; a stud bump disposed on each of the electrical connecting pads; an encapsulant formed on the chip with part of the stud bumps being exposed from the encapsulant; and a metal conductive layer formed on the encapsulant and connected to the stud bumps. The invention is characterized by completing the packaging process on the wafer directly to enable thinner and cheaper package structures to be fabricated within less time. This invention further provides a method for fabricating the package structure as described above. | 06-30-2011 |
20110157851 | PACKAGE STRUCTURE - A package structure includes a base body having a first encapsulant and a wiring layer embedded in and exposed from the first encapsulant. The wiring layer has a plurality of conductive traces and a plurality of first electrical contact pads. The first encapsulant has openings for exposing the first electrical contact pads, a chip electrically connected to the wiring layer, and a second encapsulant formed on the base body for covering the chip and the wiring layer, thereby providing an even surface for preventing the encapsulant from cracking when the chip is mounted. | 06-30-2011 |
20120001328 | CHIP-SIZED PACKAGE AND FABRICATION METHOD THEREOF - A chip-sized package and a fabrication method thereof are provided. The method includes forming a protection layer on an active surface of a chip and attaching a non-active surface of the chip to a carrier made of a hard material; performing a molding process and removing a protection layer from the chip; performing an RDL process to prevent problems as encountered in the prior art, such as softening of adhesive films, an encapsulant overflow, a pliable chip and chip deviation or contamination caused by directly adhering the active surface of the chip to the adhesive film that may even lead to inferior electrical contacts between a circuit layer and a plurality of chip bond pads during subsequent RDL process, and cause the package to be scraped. Further, the carrier employed in this invention can be repetitively used in the process to help reduce manufacturing costs. | 01-05-2012 |
20140183755 | SEMICONDUCTOR PACKAGE AND FABRICATION METHOD THEREOF - A semiconductor package is provided, which includes a carrier having a mounting area and at least a grounding pad; a substrate body having opposite first and second surfaces and a plurality of conductive vias each having a first end exposed from the first surface and a second end opposite to the first end, the substrate body being disposed on the mounting area of the carrier through the second surface thereof; a metal layer formed on the first surface of the substrate body and exposing the first ends of the conductive vias; a conductive body electrically connecting the metal layer and the grounding pad; and a semiconductor element disposed on the substrate body and electrically connected to the first ends of the conductive vias, thereby achieving an EMI shielding effect to prevent interference between electromagnetic waves or electrical signals of the substrate body and the semiconductor element. | 07-03-2014 |