Patent application number | Description | Published |
20080211070 | Flip chip contact (FCC) power package - This invention discloses a power device package for containing, protecting and providing electrical contacts for a power transistor. The power device package includes a top and bottom lead frames for directly no-bump attaching to the power transistor. The power transistor is attached to the bottom lead frame as a flip-chip with a source contact and a gate contact directly no-bumping attaching to the bottom lead frame. The power transistor has a bottom drain contact attaching to the top lead frame. The top lead frame further includes an extension for providing a bottom drain electrode substantially on a same side with the bottom lead frame. In a preferred embodiment, the power device package further includes a joint layer between device metal of source, gate or drain and top or bottom lead frame, through applying ultrasonic energy. In another embodiment, a layer of conductive epoxy or adhesive, a solder paste, a carbon paste, or other types of attachment agents for direct no-bumping attaching the power transistor to one of the top and bottom lead frames. | 09-04-2008 |
20080242052 | Method of forming ultra thin chips of power devices - A method for making thin semiconductor devices is disclosed. Starting from wafer with pre-fabricated front-side devices, the method includes:
| 10-02-2008 |
20090014853 | Integrated circuit package for semiconductior devices with improved electric resistance and inductance - A semiconductor integrated circuit package having a leadframe ( | 01-15-2009 |
20090160045 | WAFER LEVEL CHIP SCALE PACKAGING - A method for making back-to-front electrical connections in a wafer level chip scale packaging process is disclosed. A wafer containing a plurality of semiconductor chips is mounted on a package substrate. Each semiconductor chip in the plurality includes one or more electrodes on an exposed back side. Scribe lines between two or more adjacent chips on the wafer are removed to form relatively wide gaps. A conductive material is applied to the back side of the semiconductor chips and in the gaps. The conductive material in the gaps between two or more of the chips is then cut through leaving conductive material on the back side and on side walls of the two or more chips. As a result, the conductive material provides an electrical connection from the electrode on the back side of the chip to the front side of the chip. | 06-25-2009 |
20090194880 | WAFER LEVEL CHIP SCALE PACKAGE AND PROCESS OF MANUFACTURE - Power wafer level chip scale package (CSP) and process of manufacture are enclosed. The power wafer level chip scale package includes all source, gate and drain electrodes located on one side of the device, which is convenient for mounting to a printed circuit board (PCB) with solder paste. | 08-06-2009 |
20090256246 | SEMICONDUCTOR PACKAGING TECHNIQUES - A semiconductor package includes a leadframe which is cup-shaped and holds a semiconductor die. The leadframe is in electrical contact with a terminal on one side of the die, and the leads of the leadframe are bent in such a way that portions of the leads are coplanar with the other side of the die, which also contains one or more terminals. A plastic capsule is formed around the leadframe and die. | 10-15-2009 |
20090278179 | CHIP SCALE SURFACE MOUNT PACKAGE FOR SEMICONDUCTOR DEVICE AND PROCESS OF FABRICATING THE SAME - A semiconductor package has contacts on both sides of the dice on a wafer scale. The back side of the wafer is attached to a metal plate. The scribe lines separating the dice expose the metal plate without extending through the metal plate. A metal layer may be formed on the front side of the dice, covering the exposed portions of the metal plate and extending to side edges of the dice. The metal layer may cover connection pads on the front side of the dice. A second set of scribe lines are made coincident with the first set. Therefore, the metal layer remains on the side edges of the dice coupling the front and the back. As a result, the package is rugged and provides a low-resistance electrical connection between the back and front sides of the dice. | 11-12-2009 |
20090321929 | Standing chip scale package - A standing chip scale package is disclosed. The standing chip scale package provides electrical connection to bumped device contacts on both sides of the chip. The package is coupleable to a printed circuit board in a standing configuration such that front and back sides of the bumped chip are substantially perpendicular to a mounting surface. A process of fabricating the standing chip scale package is also disclosed. | 12-31-2009 |
20100320531 | STANDING CHIP SCALE PACKAGE - A standing chip scale package is disclosed. The standing chip scale package provides electrical connection to bumped device contacts on both sides of the chip. The package is coupleable to a printed circuit board in a standing configuration such that front and back sides of the bumped chip are substantially perpendicular to a mounting surface. A process of fabricating the standing chip scale package is also disclosed. | 12-23-2010 |
20110076808 | Packaging configurations for vertical electronic devices using conductive traces disposed on laminated board layers - This invention discloses an electronic package for containing a vertical semiconductor chip that includes a laminated board having a via connector and conductive traces distributed on multiple layers of the laminated board connected to the via connector. The semiconductor chip having at least one electrode connected to the conductive traces for electrically connected to the conductive traces at a different layer on the laminated board and the via connector dissipating heat generated from the vertical semiconductor. A ball grid array (BGA) connected to the via connector functioning as contact at a bottom surface of the package for mounting on electrical terminals disposed on a printed circuit board (PCB) wherein the laminated board having a thermal expansion coefficient in substantially a same range the PCB whereby the BGA having a reliable electrical contact with the electrical terminals. | 03-31-2011 |
20110108896 | WAFER LEVEL CHIP SCALE PACKAGE AND PROCESS OF MANUFACTURE - Power wafer level chip scale package (CSP) and process of manufacture are enclosed. The power wafer level chip scale package includes all source, gate and drain electrodes located on one side of the device, which is convenient for mounting to a printed circuit board (PCB) with solder paste. | 05-12-2011 |
20110143499 | Vertically packaged MOSFET and IC power devices as integrated module using 3D interconnected laminates - An electronic package for containing at least a top packaging module vertically stacked on a bottom packaging module. Each of the packaging modules includes a semiconductor chip packaged and connected by via connectors and connectors disposed on a laminated board fabricated with a standard printed-circuit board process wherein the top and bottom packaging module further configured as a surface mountable modules for conveniently stacking and mounting to prearranged electrical contacts without using a leadframe. At least one of the top and bottom packaging modules is a multi-chip module (MCM) containing at least two semiconductor chips. At least one of the top and bottom packaging modules includes a ball grid array (BGA) for surface mounting onto the prearranged electrical contacts. At least one of the top and bottom packaging modules includes a plurality of solder bumps on one of the semiconductor chips for surface mounting onto the prearranged electrical contacts. The laminated board of the bottom packaging modules further has a thermal expansion coefficient substantially the same as a printed circuit board (PCB) whereby a surface mount onto the PCB is less impacted by a temperature change | 06-16-2011 |
20110193208 | SEMICONDUCTOR PACKAGE OF A FLIPPED MOSFET AND ITS MANUFACTURING METHOD - The invention relates to a semiconductor package of a flip chip and a method for making the semiconductor package. The semiconductor chip comprises a metal-oxide-semiconductor field effect transistor. On a die paddle including a first base, a second base and a third base, half-etching or punching is performed on the top surfaces of the first base and the second base to obtain plurality of grooves that divide the top surface of the first base into a plurality of areas comprising multiple first connecting areas, and divide the top surface of the second base into a plurality of areas comprising at least a second connecting area. The semiconductor chip is connected to the die paddle at the first connecting areas and the second connecting area. | 08-11-2011 |
20110221005 | Integrated circuit package for semiconductior devices with improved electric resistance and inductance - A semiconductor integrated circuit package having a leadframe ( | 09-15-2011 |
20110227205 | MULTI-LAYER LEAD FRAME PACKAGE AND METHOD OF FABRICATION - The present invention features a lead-frame package, having a first, second, third and fourth electrically conductive structures with a pair of semiconductor dies disposed therebetween defining a stacked structure. The first and second structures are spaced-apart from and in superimposition with the first structure. A semiconductor die is disposed between the first and second structures. The semiconductor die has contacts electrically connected to the first and second structures. A part of the third structure lies in a common plane with a portion of the second structure. The third structure is coupled to the semiconductor die. An additional semiconductor die is attached to one of the first and second structures. The fourth structure is in electrical contact with the additional semiconductor die. A molding compound is disposed to encapsulate a portion of said package with a sub-portion of the molding compound being disposed in the volume. | 09-22-2011 |
20110227207 | STACKED DUAL CHIP PACKAGE AND METHOD OF FABRICATION - The present invention is directed to a lead-frame having a stack of semiconductor dies with interposed metalized clip structure. Level projections extend from the clip structure to ensure that the clip structure remains level during fabrication. | 09-22-2011 |
20110241214 | Virtually Substrate-less Composite Power Semiconductor Device and Method - A virtually substrate-less composite power semiconductor device (VSLCPSD) and method are disclosed. The VSLCPSD has a power semiconductor device (PSD), a front-face device carrier (FDC) made out of a carrier material and an intervening bonding layer (IBL). Both carrier and IBL material can be conductive or non-conductive. The PSD has back substrate portion, front semiconductor device portion with patterned front-face device metallization pads and a virtually diminishing thickness T | 10-06-2011 |
20110309454 | COMBINED PACKAGED POWER SEMICONDUCTOR DEVICE - A combined packaged power semiconductor device includes a flipped top source low-side MOSFET electrically connected to a top surface of a die paddle, a first metal interconnection plate connecting between a bottom drain of a high-side MOSFET or a top source of a flipped high-side MOSFET to a bottom drain of the low-side MOSFET, and a second metal interconnection plate stacked on top of the high-side MOSFET chip. The high-side, low-side MOSFET and the IC controller can be packaged three-dimensionally that reduces the overall size of semiconductor devices and can maximize the chip's size within a package of the same size and improves the performance of the semiconductor devices. The top source of flipped low-side MOSFET is connected to the top surface of the die paddle and thus is grounded through the exposed bottom surface of die paddle, which simplifies the shape of exposed bottom surface of the die paddle and maximizes the area to facilitate heat dissipation. | 12-22-2011 |
20120025298 | WAFER LEVEL CHIP SCALE PACKAGE - A semiconductor device, a method of manufacturing semiconductor devices and a circuit package assembly are described. A semiconductor device can have a semiconductor substrate with first and second surfaces and a sidewall between them. First and second conductive pads on the first and second surfaces are in electrical contact with corresponding first and second semiconductor device structures in the substrate. An insulator layer on the first surface and sidewall covers a portion of the first conductive pad on the first surface. An electrically conductive layer on part of the insulator layer on the first conductive pad and sidewall is in electrical contact with the second conductive pad. The insulator layer prevents the conductive layer from making electrical contact between the first and second conductive pads. | 02-02-2012 |
20120032259 | BOTTOM SOURCE POWER MOSFET WITH SUBSTRATELESS AND MANUFACTURING METHOD THEREOF - A bottom source power metal-oxide-semiconductor field-effect transistor (MOSFET) device includes a gate electrode and a source electrode formed on an initial insulation layer on a first surface of a semiconductor chip and a drain electrode formed on a second surface of the semiconductor chip. The source electrode includes a source metal, a source electrode bump formed on the source metal and a source electrode metal layer on top of the source electrode bump. A first insulation layer covers the gate electrode. A through via aligned to the gate electrode is formed from the second surface of the chip to expose a portion of the gate electrode from the second surface. | 02-09-2012 |
20120061813 | Package Structure for DC-DC Converter - A package structure for DC-DC converter disclosed herein can reduce the number of encapsulated elements as a low-side MOSFET chip can be stacked above the high-side MOSFET chip of a first die pad, through die pads of different thicknesses or interposers with joint parts of different thicknesses; moreover, it further reduces the size of the entire semiconductor package as a number of bond wires are contained in the space between the controller and the low-side MOSFET chip. Moreover, electrical connection between the top source electrode pin and the bottom source electrode pin of the low-side MOSFET chip is realized with a metal joint plate, such that when the DC-DC converter is sealed with plastic, the metal joint plate can be exposed outside to improve the thermal performance and effectively reduce the thickness of the semiconductor package. | 03-15-2012 |
20120104580 | SUBSTRATELESS POWER DEVICE PACKAGES - A substrate-less composite power semiconductor device may include a thin substrate and a top metal layer located on a top surface of the substrate. A total thickness of the substrate and the epitaxial layer may be less than 25 microns. Solder bumps are formed on top of the top metal layer and molding compound surrounds the solder bumps and leaves the solder bumps at least partly exposed. | 05-03-2012 |
20120146202 | Top exposed Package and Assembly Method - A semiconductor package and it manufacturing method includes a lead frame having a die pad, and a source lead with substantially a V groove disposed on a top surface. A semiconductor chip disposed on the die pad. A metal plate connected to a top surface electrode of the chip having a bent extension terminated in the V groove in contact with at least one of the V groove sidewalls. | 06-14-2012 |
20120205803 | PACKAGING CONFIGURATIONS FOR VERTICAL ELECTRONIC DEVICES USING CONDUCTIVE TRACES DISPOSED ON LAMINATED BOARD LAYERS - This invention discloses an electronic package for containing a vertical semiconductor chip that includes a laminated board having a via connector and conductive traces distributed on multiple layers of the laminated board connected to the via connector. The semiconductor chip having at least one electrode connected to the conductive traces for electrically connected to the conductive traces at a different layer on the laminated board and the via connector dissipating heat generated from the vertical semiconductor. A ball grid array (BGA) connected to the via connector functioning as contact at a bottom surface of the package for mounting on electrical terminals disposed on a printed circuit board (PCB) wherein the laminated board having a thermal expansion coefficient in substantially a same range the PCB whereby the BGA having a reliable electrical contact with the electrical terminals. | 08-16-2012 |
20120235289 | POWER DEVICE WITH BOTTOM SOURCE ELECTRODE AND PREPARATION METHOD - A power semiconductor package has an ultra thin chip with front side molding to reduce substrate resistance; a lead frame unit with grooves located on both side leads provides precise positioning for connecting numerous bridge-shaped metal clips to the front side of the side leads. The bridge-shaped metal clips are provided with bridge structure and half or fully etched through holes for relieving superfluous solder during manufacturing process. | 09-20-2012 |
20120235306 | Virtually Substrate-less Composite Power Semiconductor Device - A virtually substrate-less composite power semiconductor device (VSLCPSD) and method are disclosed. The VSLCPSD has a power semiconductor device (PSD), a front-face device carrier (FDC) made out of a carrier material and an intervening bonding layer (IBL). Both carrier and IBL material can be conductive or non-conductive. The PSD has back substrate portion, front semiconductor device portion with patterned front-face device metallization pads and a virtually diminishing thickness T | 09-20-2012 |
20120248593 | PACKAGE STRUCTURE FOR DC-DC CONVERTER - A package structure for DC-DC converter disclosed herein can reduce the number of encapsulated elements as a low-side MOSFET chip can be stacked above the high-side MOSFET chip of a first die pad, through die pads of different thicknesses or interposers with joint parts of different thicknesses; moreover, it further reduces the size of the entire semiconductor package as a number of bond wires are contained in the space between the controller and the low-side MOSFET chip. Moreover, electrical connection between the top source electrode pin and the bottom source electrode pin of the low-side MOSFET chip is realized with a metal joint plate, such that when the DC-DC converter is sealed with plastic, the metal joint plate can be exposed outside to improve the thermal performance and effectively reduce the thickness of the semiconductor package. | 10-04-2012 |
20120299119 | STACKED POWER SEMICONDUCTOR DEVICE USING DUAL LEAD FRAME AND MANUFACTURING METHOD - A stacked power semiconductor device includes vertical metal oxide semiconductor field-effect transistors and dual lead frames packaged with flip-chip technology. In the method of manufacturing the stacked power semiconductor device, a first semiconductor chip is flip chip mounted on the first lead frame. A mounting clips is connected to the electrode at back side of the first semiconductor chip. A second semiconductor chip is mounted on the second lead frame, which is then flipped and stacked on the mounting clip. | 11-29-2012 |
20130029461 | METHODS FOR FABRICATING ANODE SHORTED FIELD STOP INSULATED GATE BIPOLAR TRANSISTOR - A method for fabricating an anode-shorted field stop insulated gate bipolar transistor (IGBT) comprises selectively forming first and second semiconductor implant regions of opposite conductivity types. A field stop layer of a second conductivity type can be grown onto or implanted into the substrate. An epitaxial layer can be grown on the substrate or on the field stop layer. One or more insulated gate bipolar transistors (IGBT) component cells are formed within the epitaxial layer. | 01-31-2013 |
20130037935 | WAFER LEVEL PACKAGE STRUCTURE AND THE FABRICATION METHOD THEREOF - The present invention relates to a package for semiconductor device and the fabrication method for integrally encapsulating a whole semiconductor chip within a molding compound. In the semicondcutor device package, bonding pads distributed on the top of the chip are redistributed into an array of redistributed bonding pads located in an dielectric layer by utilizing the redistribution technique. The electrodes or signal terminals on the top of the semiconductor chip are connected to an electrode metal segment on the bottom of the chip by conductive materials filled in through holes formed in a silicon substrate of a semiconductor wafer. Furthermore, the top molding portion and the bottom molding portion seal the semiconductor chip completely, thus providing optimum mechanical and electrical protections. | 02-14-2013 |
20130119393 | Vertical Gallium Nitride Schottky Diode - A vertical conduction nitride-based Schottky diode is formed using an insulating substrate which was lifted off after the diode device is encapsulated on the front side with a wafer level molding compound. The wafer level molding compound provides structural support on the front side of the diode device to allow the insulating substrate to be lifted off so that a conductive layer can be formed on the backside of the diode device as the cathode electrode. A vertical conduction nitride-based Schottky diode is thus realized. In another embodiment, a protection circuit for a vertical GaN Schottky diode employs a silicon-based vertical PN junction diode connected in parallel to the GaN Schottky diode to divert reverse bias avalanche current. | 05-16-2013 |
20130130443 | METHOD FOR PACKAGING ULTRA-THIN CHIP WITH SOLDER BALL THERMO-COMPRESSION IN WAFER LEVEL PACKAGING PROCESS - The invention generally relates to a packaging method of an ultra-thin chip, more specifically, the invention relates to a method for packaging the ultra-thin chip with solder ball thermo-compression in wafer level packaging process. The method starts with disposing solder balls on metal pads arranged on the front surface of semiconductor chips that are formed at the front surface of a semiconductor wafer. The solder balls are soften by heating the wafer, a compression plate is applied with a pressure on the top ends of the solder balls thus forming a co-planar top surface at the top ends of the solder balls. A molding compound is deposited on the front surface of the wafer with the top ends of the solder balls exposed. The wafer is then ground from its back surface to reduce its thickness to achieve ultra-thin chip. | 05-23-2013 |
20130134502 | WAFER LEVEL CHIP SCALE PACKAGE - A semiconductor device, a method of manufacturing semiconductor devices and a circuit package assembly are described. A semiconductor device can have a semiconductor substrate with first and second surfaces and a sidewall between them. First and second conductive pads on the first and second surfaces are in electrical contact with corresponding first and second semiconductor device structures in the substrate. An insulator layer on the first surface and sidewall covers a portion of the first conductive pad on the first surface. An electrically conductive layer on part of the insulator layer on the first conductive pad and sidewall is in electrical contact with the second conductive pad. The insulator layer prevents the conductive layer from making electrical contact between the first and second conductive pads. | 05-30-2013 |
20130210195 | PACKAGING METHOD OF MOLDED WAFER LEVEL CHIP SCALE PACKAGE (WLCSP) - A WLCSP method comprises: depositing a metal bump on bonding pads of chips; forming a first packaging layer at front surface of wafer to cover metal bumps while forming an un-covered ring at the edge of wafer to expose the ends of each scribe line located between two adjacent chips; thinning first packaging layer to expose metal bumps; forming a groove on front surface of first packaging layer along each scribe line by cutting along a straight line extended by two ends of scribe line exposed on front surface of un-covered ring; grinding back surface of wafer to form a recessed space and a support ring at the edge of the wafer; depositing a metal layer at bottom surface of wafer in recessed space; cutting off the edge portion of wafer; and separating individual chips from wafer by cutting through first packaging layer, the wafer and metal layer along groove. | 08-15-2013 |
20130210215 | PACKAGING METHOD WITH BACKSIDE WAFER DICING - A packaging method with backside wafer dicing includes the steps of forming a support structure at the front surface of the wafer then depositing a metal layer on a centre area of the backside of the wafer after grinding the wafer backside to reduce the wafer thickness; detecting from the backside of the wafer sections of scribe lines formed in the front surface in the region between the edge of the metal layer and the edge of the wafer and cutting the wafer and the metal layer from the wafer backside along a straight line formed by extending a scribe line section detected from the wafer backside. | 08-15-2013 |
20130302946 | MULTI-LAYER LEAD FRAME PACKAGE AND METHOD OF FABRICATION - The present invention features a method for fabricating a lead-frame package, having a first, second, third and fourth electrically conductive structures with a pair of semiconductor dies disposed therebetween defining a stacked structure. The first and second structures are spaced-apart from and in superimposition with the first structure. A semiconductor die is disposed between the first and second structures. The semiconductor die has contacts electrically connected to the first and second structures. A part of the third structure lies in a common plane with a portion of the second structure. The third structure is coupled to the semiconductor die. | 11-14-2013 |
20140035116 | Top Exposed Semiconductor Chip Package - A semiconductor package and it manufacturing method includes a lead frame having a die pad, and a source lead with substantially a V groove disposed on a top surface. A semiconductor chip disposed on the die pad. A metal plate connected to a top surface electrode of the chip having a bent extension terminated in the V groove in contact with at least one of the V groove sidewalls. | 02-06-2014 |
20140091446 | SEMICONDUCTOR DEVICE EMPLOYING ALUMINUM ALLOY LEAD-FRAME WITH ANODIZED ALUMINUM - A semiconductor device comprises an aluminum alloy lead-frame with a passivation layer covering an exposed portion of the aluminum alloy lead-frame. Since aluminum alloy is a low-cost material, and its hardness and flexibility are suitable for deformation process, such as punching, bending, molding and the like, aluminum alloy lead frame is suitable for mass production; furthermore, since its weight is much lower than copper or iron-nickel material, aluminum alloy lead frame is very convenient for the production of semiconductor devices. | 04-03-2014 |
20140117523 | STACKED DUAL-CHIP PACKAGING STRUCTURE AND PREPARATION METHOD THEREOF - The invention relates to a power semiconductor device and a preparation method, particularly relates to preparation of stacked dual-chip packaging structure of MOSFET (Metal-Oxide-Semiconductor Field Effect Transistor) using flip chip technology with two interconnecting plates. The first chip is flipped and attached on the base such that the first chip is overlapped with the third pin; the back metal layer of the first chip is connected to the bonding strip of the first pin through a first interconnecting plate; the second chip is flipped and attached on a main plate portion of the first interconnecting plate such that the second chip is overlapped with the fourth pin; and the back metal layer of the second chip is connected to the bonding strip of the second pin through the second interconnecting plate. | 05-01-2014 |
20140175628 | COPPER WIRE BONDING STRUCTURE IN SEMICONDUCTOR DEVICE AND FABRICATION METHOD THEREOF - A semiconductor device comprises a first top electrode and a second top electrode at a front surface of the die, at least a Ni plating layer and an Au plating layer overlaying the Ni plating layer are formed on each of the first top electrode and the second top electrode. A copper clip attaches on the Au plating layer of the second top electrode. A gold (Au) stud bump is formed on the Au plating layer of the first top electrode with a copper wire connected on the stud bump. The Au stud bump is thicker than a thickness of the Au plating layer and thinner than a thickness of the copper clip to avoid copper wire NSOP (non-stick on pad) problem due to Ni plating layer diffusion during the solder reflow process in the copper clip attachment. | 06-26-2014 |
20140191334 | STACKED POWER SEMICONDUCTOR DEVICE USING DUAL LEAD FRAME - A stacked power semiconductor device includes vertical metal oxide semiconductor field-effect transistors and dual lead frames packaged with flip-chip technology. In the method of manufacturing the stacked power semiconductor device, a first semiconductor chip is flip chip mounted on the first lead frame. A mounting clips is connected to the electrode at back side of the first semiconductor chip. A second semiconductor chip is mounted on the second lead frame, which is then flipped and stacked on the mounting clip. | 07-10-2014 |
20140239383 | WAFER LEVEL CHIP SCALE PACKAGE AND PROCESS OF MANUFACTURE - Power wafer level chip scale package (CSP) and process of manufacture are enclosed. The power wafer level chip scale package includes all source, gate and drain electrodes located on one side of the device, which is convenient for mounting to a printed circuit board (PCB) with solder paste. | 08-28-2014 |
20140242756 | METHOD FOR PREPARING SEMICONDUCTOR DEVICES APPLIED IN FLIP CHIP TECHNOLOGY - A method for preparing semiconductor devices in a flip chip process comprises forming deep grooves surrounding each of the semiconductor chips; depositing a first plastic package material to form a first plastic package layer covering front surface of the semiconductor wafer and filling the deep grooves; depositing a metal layer at back surface of the semiconductor wafer after grinding; grinding an outermost portion of the metal layer thus forming a ring area located at back surface around edge of the semiconductor wafer not covered by the metal layer; cutting the first plastic package layer, the semiconductor wafer, the metal layer and the first plastic package material filled in the deep grooves along a straight line formed by two ends of each of the deep grooves filled with the first plastic package material; and picking up the semiconductor devices and mounting on a substrate without flipping the semiconductor devices. | 08-28-2014 |
20140252372 | VERTICAL GALLIUM NITRIDE SCHOTTKY DIODE - A vertical conduction nitride-based Schottky diode is formed using an insulating substrate which was lifted off after the diode device is encapsulated on the front side with a wafer level molding compound. The wafer level molding compound provides structural support on the front side of the diode device to allow the insulating substrate to be lifted off so that a conductive layer can be formed on the backside of the diode device as the cathode electrode. A vertical conduction nitride-based Schottky diode is thus realized. In another embodiment, a protection circuit for a vertical GaN Schottky diode employs a silicon-based vertical PN junction diode connected in parallel to the GaN Schottky diode to divert reverse bias avalanche current. | 09-11-2014 |
20140264805 | Semiconductor Package And Fabrication Method Thereof - A method of making a semiconductor packaged device comprises mounting onto a lead frame a bottom of a molded semiconductor chip having a first plastic package body covering a top face of a semiconductor chip, encapsulating the lead frame and the semiconductor chip with a second plastic package body with top surfaces of conductive contact bodies electrically connected to electrodes on the top surface of the semiconductor chip exposed and plating conductive pads on a top surface of the assembly structure to provide external electrical connections to the electrodes through the conductive contact bodies. | 09-18-2014 |
20140315350 | WAFER PROCESS FOR MOLDED CHIP SCALE PACKAGE (MCSP) WITH THICK BACKSIDE METALLIZATION - A wafer process for MCSP comprises: depositing a metal bump on bonding pads of chips; forming a first packaging layer at front surface of wafer covering metal bumps while forming an un-covered ring at the edge of wafer to expose the ends of each scribe line located between two adjacent chips; thinning first packaging layer to expose metal bumps; grinding back surface of wafer to form a recessed space and a support ring at the edge of the wafer; depositing a metal seed layer and a thick metal layer at bottom surface of wafer in recessed space in a sequence; cutting off the edge portion of wafer; and separating individual chips from wafer by cutting through first packaging layer, the wafer and the metal seed and metal layers along the scribe line. | 10-23-2014 |
20140319601 | BOTTOM SOURCE SUBSTRATELESS POWER MOSFET - A bottom source power metal-oxide-semiconductor field-effect transistor (MOSFET) device includes a gate electrode and a source electrode formed on an initial insulation layer on a first surface of a semiconductor chip and a drain electrode formed on a second surface of the semiconductor chip. The source electrode includes a source metal, a source electrode bump formed on the source metal and a source electrode metal layer on top of the source electrode bump. A first insulation layer covers the gate electrode. A through via aligned to the gate electrode is formed from the second surface of the chip to expose a portion of the gate electrode from the second surface. | 10-30-2014 |
20140361418 | A SEMICONDUCTOR PACKAGE OF A FLIPPED MOSFET - The invention relates to a semiconductor package of a flip chip and a method for making the semiconductor package. The semiconductor chip comprises a metal-oxide-semiconductor field effect transistor. On a die paddle including a first base, a second base and a third base, half-etching or punching is performed on the top surfaces of the first base and the second base to obtain plurality of grooves that divide the top surface of the first base into a plurality of areas comprising multiple first connecting areas, and divide the top surface of the second base into a plurality of areas comprising at least a second connecting area. The semiconductor chip is connected to the die paddle at the first connecting areas and the second connecting area. | 12-11-2014 |
20150021753 | PACKAGING STRUCTURE OF A SEMICONDUCTOR DEVICE - A method of making a semiconductor packaged device comprises mounting onto a lead frame a bottom of a molded semiconductor chip having a first plastic package body covering a top face of a semiconductor chip, encapsulating the lead frame and the semiconductor chip with a second plastic package body with top surfaces of conductive contact bodies electrically connected to electrodes on the top surface of the semiconductor chip exposed and plating conductive pads on a top surface of the assembly structure to provide external electrical connections to the electrodes through the conductive contact bodies. | 01-22-2015 |
20150056752 | SUBSTRATELESS POWER DEVICE PACKAGES - A substrate-less composite power semiconductor device may be fabricated from a vertical conductive power semiconductor device wafer that includes a top metal layer located on a top surface of the wafer by a) forming solder bumps on top of the top metal layer; b) forming wafer level molding around the solder bumps such that the solder bumps are exposed through a top of the wafer level molding; c) grinding a back side of the device wafer to reduce a total thickness of a semiconductor material portion of the device wafer to a final thickness; and d) forming a back metal on a back surface of the wafer. | 02-26-2015 |
20150087114 | METHOD FOR PACKAGING A POWER DEVICE WITH BOTTOM SOURCE ELECTRODE - A power semiconductor package has an ultra thin chip with front side molding to reduce substrate resistance; a lead frame unit with grooves located on both side leads provides precise positioning for connecting numerous bridge-shaped metal clips to the front side of the side leads. The bridge-shaped metal clips are provided with bridge structure and half or fully etched through holes for relieving superfluous solder during manufacturing process. | 03-26-2015 |