Patent application number | Description | Published |
20100133705 | APPARATUS AND METHOD FOR REDUCING PITCH IN AN INTEGRATED CIRCUIT - An apparatus and method, the apparatus includes an electronic chip package including an electronic chip having a first and a second contact pad formed thereon, a first dielectric layer coupled to the electronic chip, a second dielectric layer coupled to the first dielectric layer such that a dielectric boundary lies therebetween, a first and a second cover pad positioned along the dielectric boundary, a metal interconnect formed along a first multi-layer via and coupled to the first cover pad and contact pad, and a metal interconnect formed along a second multi-layer via and coupled to the second cover pad and contact pad. The first multi-layer via extends through the second dielectric layer, the first cover pad, and the first dielectric layer to the first contact pad. The second multi-layer via extends through the second dielectric layer, the second cover pad, and the first dielectric layer to the second contact pad. | 06-03-2010 |
20100224992 | SYSTEM AND METHOD FOR STACKED DIE EMBEDDED CHIP BUILD-UP - An embedded chip package (ECP) includes a plurality of re-distribution layers joined together in a vertical direction to form a lamination stack, each re-distribution layer having vias formed therein. The embedded chip package also includes a first chip embedded in the lamination stack and a second chip attached to the lamination stack and stacked in the vertical direction with respect to the first chip, each of the chips having a plurality of chip pads. The embedded chip package further includes an input/output (I/O) system positioned on an outer-most re-distribution layer of the lamination stack and a plurality of metal interconnects electrically coupled to the I/O system to electrically connect the first and second chips to the I/O system. Each of the plurality of metal interconnects extends through a respective via to form a direct metallic connection with a metal interconnect on a neighboring re-distribution layer or a chip pad on the first or second chip. | 09-09-2010 |
20110215480 | STRESS RESISTANT MICRO-VIA STRUCTURE FOR FLEXIBLE CIRCUITS - A chip package is disclosed that includes an electronic chip having a plurality of die pads formed on a top surface thereof, with a polyimide flex layer positioned thereon by way of an adhesive layer. A plurality of vias is formed through the polyimide flex layer and the adhesive layer corresponding to the die pads. A plurality of metal interconnects are formed on the polyimide flex layer each having a cover pad covering a portion of a top surface of the polyimide flex layer, a sidewall extending down from the cover pad and through the via along a perimeter thereof, and a base connected to the sidewall and forming an electrical connection with a respective die pad. Each of the base and the sidewall is formed to have a thickness that is equal to or greater than a thickness of the adhesive layer. | 09-08-2011 |
20110316167 | ELECTRICAL INTERCONNECT FOR AN INTEGRATED CIRCUIT PACKAGE AND METHOD OF MAKING SAME - An interconnect assembly for an embedded chip package includes a dielectric layer, first metal layer comprising upper contact pads, second metal layer comprising lower contact pads, and metalized connections formed through the dielectric layer and in contact with the upper and lower contact pads to form electrical connections therebetween. A first surface of the upper contact pads is affixed to a top surface of the dielectric layer and a first surface of the lower contact pads is affixed to a bottom surface of the dielectric layer. An input/output (I/O) of a first side of the interconnect assembly is formed on a surface of the lower contact pads that is opposite the first surface of the lower contact pads, and an I/O of a second side of the interconnect assembly is formed on a surface of the upper contact pads that is opposite the first surface of the upper contact pads. | 12-29-2011 |
20120018857 | SYSTEM AND METHOD OF CHIP PACKAGE BUILD-UP - A system and method for chip package fabrication is disclosed. The chip package includes a base re-distribution layer having an opening formed therein, an adhesive layer having a window formed therein free of adhesive material, and a die affixed to the base re-distribution layer by way of the adhesive layer, the die being aligned with the window such that only a perimeter of the die contacts the adhesive layer. A shield element is positioned between the base re-distribution layer and adhesive layer that is generally aligned with the opening formed in the base re-distribution layer and the window of the adhesive layer such that only a perimeter of the shield element is attached to the adhesive layer. The shield element is separated from the die by an air gap and is configured to be selectively removable from the adhesive layer so as to expose the front surface of the die. | 01-26-2012 |
20120146234 | SEMICONDUCTOR DEVICE PACKAGE AND METHOD OF MANUFACTURING THEREOF - A semiconductor device package includes a semiconductor device having connection pads formed thereon, with the connection pads being formed on first and second surfaces of the semiconductor device with edges of the semiconductor device extending therebetween. A first passivation layer is applied on the semiconductor device and a base dielectric laminate is affixed to the first surface of the semiconductor device that has a thickness greater than that of the first passivation layer. A second passivation layer having a thickness greater than that of the first passivation layer is applied over the first passivation layer and the semiconductor device to cover the second surface and the edges of the semiconductor device, and metal interconnects are coupled to the connection pads, with the metal interconnects extending through vias formed through the first and second passivation layers and the base dielectric laminate sheet to form a connection with the connection pads. | 06-14-2012 |
20120161325 | SEMICONDUCTOR DEVICE PACKAGE - A semiconductor device package is provided. The semiconductor device package includes a laminate comprising a first metal layer disposed on a dielectric film; a plurality of vias extending through the laminate according to a predetermined pattern; one or more semiconductor devices attached to the dielectric film such that the semiconductor device contacts one or more vias; a patterned interconnect layer disposed on dielectric film, said patterned interconnect layer comprising one or more patterned regions of the first metal layer and an electrically conductive layer, wherein a portion of the patterned interconnect layer extends through one or more vias to form an electrical contact with the semiconductor device. The patterned interconnect layer comprises a top interconnect region and a via interconnect region, wherein the package interconnect region has a thickness greater than a thickness of the via interconnect region. | 06-28-2012 |
20120329207 | SEMICONDUCTOR DEVICE PACKAGE AND METHOD OF MANUFACTURING THEREOF - A semiconductor device package includes a semiconductor device having connection pads formed thereon, with the connection pads being formed on first and second surfaces of the semiconductor device with edges of the semiconductor device extending therebetween. A first passivation layer is applied on the semiconductor device and a base dielectric laminate is affixed to the first surface of the semiconductor device that has a thickness greater than that of the first passivation layer. A second passivation layer having a thickness greater than that of the first passivation layer is applied over the first passivation layer and the semiconductor device to cover the second surface and the edges of the semiconductor device, and metal interconnects are coupled to the connection pads, with the metal interconnects extending through vias formed through the first and second passivation layers and the base dielectric laminate sheet to form a connection with the connection pads. | 12-27-2012 |
20130043571 | POWER OVERLAY STRUCTURE WITH LEADFRAME CONNECTIONS - A power overlay (POL) packaging structure that incorporates a leadframe connection is disclosed. The a POL structure includes a POL sub-module having a dielectric layer, at least one semiconductor device attached to the dielectric layer and that includes a substrate composed of a semiconductor material and a plurality of connection pads formed on the substrate, and a metal interconnect structure electrically coupled to the plurality of connection pads of the at least one semiconductor device, with the metal interconnect structure extending through vias formed through the dielectric layer so as to be connected to the plurality of connection pads. The POL structure also includes a leadframe electrically coupled to the POL sub-module, with the leadframe comprising leads configured to make an interconnection to an external circuit structure. | 02-21-2013 |
20130045575 | EPOXY ENCAPSULATING AND LAMINATION ADHESIVE AND METHOD OF MAKING SAME - An adhesive includes an epoxy resin and a hardener. The hardener includes trioxdiamine, diaminodicyclohexylmethane, toluene diamine, and bisphenol-A dianhydride. | 02-21-2013 |
20130214435 | EPOXY ENCAPSULATING AND LAMINATION ADHESIVE AND METHOD OF MAKING SAME - An adhesive includes an epoxy resin and a hardener. The hardener includes trioxdiamine, diaminodicyclohexylmethane, toluene diamine, and bisphenol-A dianhydride. | 08-22-2013 |
20130256900 | ULTRATHIN BURIED DIE MODULE AND METHOD OF MANUFACTURING THEREOF - A method of forming a buried die module includes providing an initial laminate flex layer and forming a die opening through the initial laminate flex layer. A first uncut laminate flex layer is secured to the first surface of the initial laminate flex layer via an adhesive and a die is positioned within the die opening of the initial laminate flex layer. A second uncut laminate flex layer is secured to the second surface of the initial laminate flex layer via an adhesive and the adhesive between each pair of neighboring layers is cured. A plurality of vias and metal interconnects are formed in and on the first and second uncut laminate flex layers, with each of the metal interconnects extending through a respective via and being directly metalized to a metal interconnect on the initial laminate flex layer or a die pad on the die. | 10-03-2013 |
20130334706 | INTEGRATED CIRCUIT PACKAGE AND METHOD OF MAKING SAME - A chip package includes a first die with an active surface having at least one die pad positioned thereon; a first adhesive layer having a first surface coupled to the active surface of the first die and a second surface opposite the first surface; and a first dielectric layer having a top surface. A first portion of the top surface of the first dielectric layer is coupled to the second surface of the first adhesive layer. A second portion of the top surface of the first dielectric layer, distinct from the first portion, is substantially free of adhesive. | 12-19-2013 |
20140029210 | DIFFUSION BARRIER FOR SURFACE MOUNT MODULES - A surface-mount package structure for reducing the ingress of moisture and gases thereto is disclosed. The surface-mount structure includes a sub-module having a dielectric layer, semiconductor devices attached to the dielectric layer, a first level interconnect structure electrically coupled to the semiconductor devices, and a second level I/O connection electrically coupled to the first level interconnect and formed on the dielectric layer, with the second level I/O connection configured to connect the sub-module to an external circuit. The semiconductor devices of the sub-module are attached to a substrate structure, with a dielectric material positioned between the dielectric layer and the substrate structure to fill in gaps in the surface-mount structure. A diffusion barrier layer is applied over the sub-module, adjacent the first and second level I/O connections, and extends down to the substrate structure to reduce the ingress of moisture and gases from a surrounding environment into the surface-mount structure. | 01-30-2014 |
20140029234 | RELIABLE SURFACE MOUNT INTEGRATED POWER MODULE - A surface mount packaging structure that yields improved thermo-mechanical reliability and more robust second-level package interconnections is disclosed. The surface mount packaging structure includes a sub-module having a dielectric layer, semiconductor devices attached to the dielectric layer, a first level metal interconnect structure electrically coupled to the semiconductor devices, and a second level I/O connection electrically coupled to the first level interconnect and formed on the dielectric layer on a side opposite the semiconductor devices, with the second level I/O connection configured to connect the sub-module to an external circuit. The semiconductor devices of the sub-module are attached to the first surface of a multi-layer substrate structure, with a dielectric material positioned between the dielectric layer and the multi-layer substrate structure to fill in gaps in the surface-mount structure and provide additional structural integrity thereto. | 01-30-2014 |
20140110866 | SYSTEM AND METHOD OF CHIP PACKAGE BUILD-UP - A system and method for chip package fabrication is disclosed. The chip package includes a base re-distribution layer having an opening formed therein, an adhesive layer having a window formed therein free of adhesive material, and a die affixed to the base re-distribution layer by way of the adhesive layer, the die being aligned with the window such that only a perimeter of the die contacts the adhesive layer. A shield element is positioned between the base re-distribution layer and adhesive layer that is generally aligned with the opening formed in the base re-distribution layer and the window of the adhesive layer such that only a perimeter of the shield element is attached to the adhesive layer. The shield element is separated from the die by an air gap and is configured to be selectively removable from the adhesive layer so as to expose the front surface of the die. | 04-24-2014 |
20140138806 | POWER OVERLAY STRUCTURE WITH LEADFRAME CONNECTIONS - A power overlay (POL) packaging structure that incorporates a leadframe connection is disclosed. The a POL structure includes a POL sub-module having a dielectric layer, at least one semiconductor device attached to the dielectric layer and that includes a substrate composed of a semiconductor material and a plurality of connection pads formed on the substrate, and a metal interconnect structure electrically coupled to the plurality of connection pads of the at least one semiconductor device, with the metal interconnect structure extending through vias formed through the dielectric layer so as to be connected to the plurality of connection pads. The POL structure also includes a leadframe electrically coupled to the POL sub-module, with the leadframe comprising leads configured to make an interconnection to an external circuit structure. | 05-22-2014 |
20140138807 | POWER OVERLAY STRUCTURE WITH LEADFRAME CONNECTIONS - A power overlay (POL) packaging structure that incorporates a leadframe connection is disclosed. The a POL structure includes a POL sub-module having a dielectric layer, at least one semiconductor device attached to the dielectric layer and that includes a substrate composed of a semiconductor material and a plurality of connection pads formed on the substrate, and a metal interconnect structure electrically coupled to the plurality of connection pads of the at least one semiconductor device, with the metal interconnect structure extending through vias formed through the dielectric layer so as to be connected to the plurality of connection pads. The POL structure also includes a leadframe electrically coupled to the POL sub-module, with the leadframe comprising leads configured to make an interconnection to an external circuit structure. | 05-22-2014 |
20140159213 | ELECTRICAL INTERCONNECT FOR AN INTEGRATED CIRCUIT PACKAGE AND METHOD OF MAKING SAME - An interconnect assembly for an embedded chip package includes a dielectric layer, first metal layer comprising upper contact pads, second metal layer comprising lower contact pads, and metalized connections formed through the dielectric layer and in contact with the upper and lower contact pads to form electrical connections therebetween. A first surface of the upper contact pads is affixed to a top surface of the dielectric layer and a first surface of the lower contact pads is affixed to a bottom surface of the dielectric layer. An input/output (I/O) of a first side of the interconnect assembly is formed on a surface of the lower contact pads that is opposite the first surface of the lower contact pads, and an I/O of a second side of the interconnect assembly is formed on a surface of the upper contact pads that is opposite the first surface of the upper contact pads. | 06-12-2014 |
20140183750 | ULTRATHIN BURIED DIE MODULE AND METHOD OF MANUFACTURING THEREOF - A method of forming a buried die module includes providing an initial laminate flex layer and forming a die opening through the initial laminate flex layer. A first uncut laminate flex layer is secured to the first surface of the initial laminate flex layer by way of an adhesive material and a die is positioned within the die opening of the initial laminate flex layer and onto the adhesive material. A second uncut laminate flex layer is secured to the second surface of the initial laminate flex layer by way of an adhesive material and the adhesive materials are then cured. Vias and metal interconnects are formed in and on the first and second uncut laminate flex layers, with each of the metal interconnects extending through a respective via and being directly metalized to a metal interconnect on the initial laminate flex layer or a die pad on the die. | 07-03-2014 |
20140264799 | POWER OVERLAY STRUCTURE AND METHOD OF MAKING SAME - A power overlay (POL) structure includes a POL sub-module. The POL sub-module includes a dielectric layer and a semiconductor device having a top surface attached to the dielectric layer. The top surface of the semiconductor device has at least one contact pad formed thereon. The POL sub-module also includes a metal interconnect structure that extends through the dielectric layer and is electrically coupled to the at least one contact pad of the semiconductor device. A conducting shim is coupled to a bottom surface of the semiconductor device and a first side of a thermal interface is coupled to the conducting shim. A heat sink is coupled to a second side of the electrically insulating thermal interface. | 09-18-2014 |
20140264800 | POWER OVERLAY STRUCTURE AND METHOD OF MAKING SAME - A semiconductor device module includes a dielectric layer, a semiconductor device having a first surface coupled to the dielectric layer, and a conducting shim having a first surface coupled to the dielectric layer. The semiconductor device also includes an electrically conductive heatspreader having a first surface coupled to a second surface of the semiconductor device and a second surface of the conducting shim. A metallization layer is coupled to the first surface of the semiconductor device and the first surface of the conducting shim. The metallization layer extends through the dielectric layer and is electrically connected to the second surface of the semiconductor device by way of the conducting shim and the heatspreader. | 09-18-2014 |
20150069612 | RELIABLE SURFACE MOUNT INTEGRATED POWER MODULE - A surface mount packaging structure that yields improved thermo-mechanical reliability and more robust second-level package interconnections is disclosed. The surface mount packaging structure includes a sub-module having a dielectric layer, semiconductor devices attached to the dielectric layer, a first level metal interconnect structure electrically coupled to the semiconductor devices, and a second level I/O connection electrically coupled to the first level interconnect and formed on the dielectric layer on a side opposite the semiconductor devices, with the second level I/O connection configured to connect the sub-module to an external circuit. The semiconductor devices of the sub-module are attached to the first surface of a multi-layer substrate structure, with a dielectric material positioned between the dielectric layer and the multi-layer substrate structure to fill in gaps in the surface-mount structure and provide additional structural integrity thereto. | 03-12-2015 |
20150084207 | EMBEDDED SEMICONDUCTOR DEVICE PACKAGE AND METHOD OF MANUFACTURING THEREOF - A package structure includes a dielectric layer, at least one semiconductor device attached to the dielectric layer, one or more dielectric sheets applied to the dielectric layer and about the semiconductor device(s) to embed the semiconductor device(s) therein, and a plurality of vias formed to the semiconductor device(s) that are formed in at least one of the dielectric layer and the one or more dielectric sheets. The package structure also includes metal interconnects formed in the vias and on one or more outward facing surfaces of the package structure to form electrical interconnections to the semiconductor device(s). The dielectric layer is composed of a material that does not flow during a lamination process and each of the one or more dielectric sheets is composed of a curable material configured to melt and flow when cured during the lamination process so as to fill-in any air gaps around the semiconductor device(s). | 03-26-2015 |