Patent application number | Description | Published |
20080203548 | High current semiconductor power device soic package - A high current semiconductor power SOIC package is disclosed. The package includes a relatively thick lead frame formed of a single gauge material having a thickness greater than 8 mils, the lead frame having a plurality of leads and a first lead frame pad, the first lead frame pad including a die soldered thereto; a pair of lead bonding areas being disposed in a same plane of a top surface of the die; large diameter bonding wires connecting the die to the plurality of leads, the bonding wires being aluminum; and a resin body encapsulating the die, bonding wires and at least a portion of the lead frame. | 08-28-2008 |
20090008758 | USE OF DISCRETE CONDUCTIVE LAYER IN SEMICONDUCTOR DEVICE TO RE-ROUTE BONDING WIRES FOR SEMICONDUCTOR DEVICE PACKAGE - A semiconductor package assembly may include a lead frame having a die bonding pad and plurality of leads coupled to the first die bonding pad. A vertical semiconductor device may be bonded to the die bonding pad. The device may have a conductive pad electrically connected to one lead through a first bond wire. An electrically isolated conductive trace may be formed from a layer of conductive material of the first semiconductor device. The conductive trace provides an electrically conductive path between the first bond wire and a second bond wire. The conductive path may either pass underneath a third bond wire thereby avoiding the third bond wire crossing another bond wire, or the conductive path may result in a reduced length for the first and second bond wires that is less than a predetermined maximum length. | 01-08-2009 |
20090057869 | CO-PACKAGED HIGH-SIDE AND LOW-SIDE NMOSFETS FOR EFFICIENT DC-DC POWER CONVERSION - A circuit package assembly is disclosed. The assembly includes a conductive substrate; a high-side n-channel metal oxide semiconductor field effect transistor (NMOSFET) having a source on a side facing a surface of the conductive substrate and in electrical contact therewith and a low-side standard n-channel metal oxide semiconductor field effect transistor (NMOSFET) having a drain on a side facing the conductive substrate and in electrical contact therewith. Co-packaging of high-side and low-side NMOSFETs in this manner may reduce package size and parasitic inductance and capacitance compared to conventional packaging. | 03-05-2009 |
20090128968 | STACKED-DIE PACKAGE FOR BATTERY POWER MANAGEMENT - A stacked-die package for battery protection is disclosed. The battery protection package includes a power control integrated circuit (IC) stacked on top of integrated dual common-drain metal oxide semiconductor field effect transistors (MOSFETs) or two discrete MOSFETs. The power control IC is either stacked on top of one MOSFET or on top of and overlapping both two MOSFETs. | 05-21-2009 |
20090134503 | Semiconductor power device package having a lead frame-based integrated inductor - A semiconductor power device package having a lead frame-based integrated inductor is disclosed. The semiconductor power device package includes a lead frame having a plurality of leads, a inductor core attached to the lead frame such that a plurality of lead ends are exposed through a window formed in the inductor core, a plurality of bonding wires, ones of the plurality of bonding wires coupling each of the plurality of lead ends to adjacent leads about the inductor core to form the inductor, and a power integrated circuit coupled to the inductor. In alternative embodiments, a top lead frame couples each of the plurality of lead ends to adjacent leads about the inductor core by means of a connection chip. | 05-28-2009 |
20090134964 | Lead frame-based discrete power inductor - A lead frame-based discrete power inductor is disclosed. The power inductor includes top and bottom lead frames, the leads of which form a coil around a single closed-loop magnetic core. The coil includes interconnections between inner and outer contact sections of the top and bottom lead frames, the magnetic core being sandwiched between the top and bottom lead frames. Ones of the leads of the top and bottom lead frames have a generally non-linear, stepped configuration such that the leads of the top lead frame couple adjacent leads of the bottom lead frame about the magnetic core to form the coil. | 05-28-2009 |
20090167477 | Compact Inductive Power Electronics Package - An inductive power electronics package is disclosed. It has a circuit substrate with power inductor attached atop. The power inductor has inductor core of closed magnetic loop with an interior window. The closed magnetic loop can include air gap for inductance adjustment. The circuit substrate has bottom half-coil forming elements constituting a bottom half-coil beneath the inductor core. Also provided are top half-coil forming elements interconnected with the bottom half-coil forming elements to form an inductive coil enclosing the inductor core. An inner connection chip can be added in the interior window for interconnecting bottom half-coil forming elements with top half-coil forming elements. An outer connection chip can be added about the inductor core for interconnecting bottom half-coil forming elements with top half-coil forming elements outside the inductor core. A power Integrated Circuit can be attached to the top side of the circuit substrate as well. | 07-02-2009 |
20090233403 | DUAL FLAT NON-LEADED SEMICONDUCTOR PACKAGE - A DFN semiconductor package includes a leadframe having a die bonding pad formed integrally with a drain lead, a gate lead and a source lead, a die coupled to the die bonding pad, a die source bonding area coupled to the source lead and a die gate bonding area coupled to the gate lead, and an encapsulant at least partially covering the die, drain lead, gate lead and source lead. | 09-17-2009 |
20090258458 | DFN semiconductor package having reduced electrical resistance - A dual flat non-leaded semiconductor package is disclosed. A method of making a dual flat non-leaded semiconductor package includes forming a leadframe having a die bonding area with an integral drain lead, a gate lead bonding area and a source lead bonding area, the gate lead bonding area and a source lead bonding area being of increased area; bonding a die to the die bonding area; coupling a die source bonding area to the source lead bonding area; coupling a die gate bonding area to the gate lead bonding area; and partially encapsulating the die, the drain lead, the gate lead and the source lead to form the dual flat non-leaded semiconductor package. | 10-15-2009 |
20100308454 | POWER SEMICONDUCTOR DEVICE PACKAGE AND FABRICATION METHOD - A power semiconductor device package includes a conductive assembly including a connecting structure and a semiconductor die having an aperture formed therethrough, the aperture being sized and configured to spacedly receive the connecting structure. In an alternative embodiment, a power semiconductor device package includes a conductive assembly including a connecting structure and a pair of semiconductor die disposed on either side of the connecting structure in spaced relationship thereto. | 12-09-2010 |
20110068457 | Semiconductor package with adhesive material pre-printed on the lead frame and chip, and its manufacturing method - This invention discloses a semiconductor package with adhesive material pre-printed on the lead frame and chip, and the manufacturing method. The adhesive material is applied onto the chip carrier and the pin of the lead frame and also on the front electrode of the semiconductor chip via pre-printing. The back of the semiconductor chip is adhered on the chip carrier, and the front electrode of the semiconductor chip and the pin are connected respectively with a metal connector. The size, shape and thickness of the adhesive material are applied according to different application requirements according to size and shapes of the contact zone of the semiconductor chip and the metal connector. Particularly, the adhesive zones are formed by pre-printing the adhesive material thus significantly enhance the quality and performance of semiconductor products, and improves the productivity. | 03-24-2011 |
20110070698 | Semiconductor package with adhesive material pre-printed on the lead frame and chip, and its manufacturing method - This invention discloses a semiconductor package with adhesive material pre-printed on the lead frame and chip, and the manufacturing method. The adhesive material is applied onto the chip carrier and the pin of the lead frame and also on the front electrode of the semiconductor chip via pre-printing. The back of the semiconductor chip is adhered on the chip carrier, and the front electrode of the semiconductor chip and the pin are connected respectively with a metal connector. The size, shape and thickness of the adhesive material are applied according to different application requirements according to size and shapes of the contact zone of the semiconductor chip and the metal connector. Particularly, the adhesive zones are formed by pre-printing the adhesive material thus significantly enhance the quality and performance of semiconductor products, and improves the productivity. | 03-24-2011 |
20110108998 | USE OF DISCRETE CONDUCTIVE LAYER IN SEMICONDUCTOR DEVICE TO RE-ROUTE BONDING WIRES FOR SEMICONDUCTOR DEVICE PACKAGE - A semiconductor package assembly may include a lead frame having a die bonding pad and plurality of leads coupled to the first die bonding pad. A vertical semiconductor device may be bonded to the die bonding pad. The device may have a conductive pad electrically connected to one lead through a first bond wire. An electrically isolated conductive trace may be formed from a layer of conductive material of the first semiconductor device. The conductive trace provides an electrically conductive path between the first bond wire and a second bond wire. The conductive path may either pass underneath a third bond wire thereby avoiding the third bond wire crossing another bond wire, or the conductive path may result in a reduced length for the first and second bond wires that is less than a predetermined maximum length. | 05-12-2011 |
20110121934 | Lead Frame-based Discrete Power Inductor - A lead frame-based discrete power inductor is disclosed. The power inductor includes top and bottom lead frames, the leads of which form a coil around a single closed-loop magnetic core. The coil includes interconnections between inner and outer contact sections of the top and bottom lead frames, the magnetic core being sandwiched between the top and bottom lead frames. Ones of the leads of the top and bottom lead frames have a generally non-linear, stepped configuration such that the leads of the top lead frame couple adjacent leads of the bottom lead frame about the magnetic core to form the coil. | 05-26-2011 |
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 |
20110278709 | STACKED-DIE PACKAGE FOR BATTERY POWER MANAGEMENT - A battery protection package assembly is disclosed. The assembly includes a power control integrated circuit (IC) with pins for a supply voltage input (VCC) and a ground (VSS) on a first side of the power control IC. First and second common-drain metal oxide semiconductor field effect transistors (MOSFETs) are electrically coupled to the power control IC. The power control IC and the first and second common-drain metal oxide semiconductor field effect transistors (MOSFET) are co-packaged on a common die pad. The power control IC is vertically stacked on top of one or more of the first and second common-drain MOSFETs. Leads coupled to a supply voltage input (VCC) and a ground (VSS) of the power control IC are on a first side of the common die pad. | 11-17-2011 |
20120248539 | FLIP CHIP SEMICONDUCTOR DEVICE - A semiconductor device package comprises a lead frame having a die paddle comprising a first chip installation area and a second chip installation area, a recess area formed in the first chip installation area, and multiple metal pillars formed in the recess area, a notch divides the first chip installation area into a transverse base extending transversely and a longitudinal base extending longitudinally, and separates the recess area into a transverse recess part formed in the transverse base and a longitudinal recess part formed in longitudinal base; a portion of a transverse extending part connecting to an external pin extends into a portion inside of the notch. | 10-04-2012 |
20120322207 | SEMICONDUCTOR PACKAGE WITH ADHESIVE MATERIAL PRE-PRINTED ON THE LEAD FRAME AND CHIP, AND ITS MANUFACTURING METHOD - This invention discloses a semiconductor package with adhesive material pre-printed on the lead frame and chip, and the manufacturing method. The adhesive material is applied onto the chip carrier and the pin of the lead frame and also on the front electrode of the semiconductor chip via pre-printing. The back of the semiconductor chip is adhered on the chip carrier, and the front electrode of the semiconductor chip and the pin are connected respectively with a metal connector. The size, shape and thickness of the adhesive material are applied according to different application requirements according to size and shapes of the contact zone of the semiconductor chip and the metal connector. Particularly, the adhesive zones are formed by pre-printing the adhesive material thus significantly enhance the quality and performance of semiconductor products, and improves the productivity. | 12-20-2012 |
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 |
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 |
20140054758 | STACKED DUAL CHIP PACKAGE HAVING LEVELING PROJECTIONS - 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. | 02-27-2014 |
20150035129 | STACKED MULTI - CHIP PACKAGING STRUCTURE AND MANUFACTURING METHOD THEREOF - A stacked multi-chip packaging structure comprises a lead frame, a first semiconductor chip mounted on the lead frame, a second semiconductor chip flipped-chip mounted on the lead frame, a metal clip mounted on top of the first and second semiconductor chips and a third semiconductor chip stacked on the meal clip; bonding wires electrically connecting electrodes on the third semiconductor chip to the first and second semiconductor chips and the pins of the lead frame; plastic molding encapsulating the lead frame, the chips and the metal clip. | 02-05-2015 |
20150076676 | POWER SEMICONDUCTOR DEVICE PACKAGE AND FABRICATION METHOD - A power semiconductor device package includes a conductive assembly including a connecting structure and a semiconductor die having an aperture formed therethrough, the aperture being sized and configured to spacedly receive the connecting structure. In an alternative embodiment, a power semiconductor device package includes a conductive assembly including a connecting structure and a pair of semiconductor die disposed on either side of the connecting structure in spaced relationship thereto. | 03-19-2015 |