Patent application number | Description | Published |
20080311702 | METHODS FOR STACKING WIRE-BONDED INTEGRATED CIRCUIT DICE ON FLIP-CHIP BONDED INTEGRATED CIRCUIT DICE - An inventive electronic device, such as a multi-chip module (MCM), a Single In-line Memory Module (SIMM), or a Dual In-line Memory Module (DIMM), includes a base, such as a printed circuit board, having a surface on which flip-chip pads and wire-bondable pads are provided. The flip-chip pads define an area on the surface of the base at least partially bounded by the wire-bondable pads. A first integrated circuit (IC) die is flip-chip bonded to the flip-chip pads, and a second IC die is back-side attached to the first IC die and then wire-bonded to the wire-bondable pads. As a result, the flip-chip mounted first IC die is stacked with the second IC die in a simple, novel manner. | 12-18-2008 |
20080315435 | METHODS FOR STACKING WIRE-BONDED INTEGRATED CIRCUIT DICE ON FLIP-CHIP BONDED INTEGRATED CIRCUIT DICE - An inventive electronic device, such as a multi-chip module (MCM), a Single In-line Memory Module (SIMM), or a Dual In-line Memory Module (DIMM), includes a base, such as a printed circuit board, having a surface on which flip-chip pads and wire-bondable pads are provided. The flip-chip pads define an area on the surface of the base at least partially bounded by the wire-bondable pads. A first integrated circuit (IC) die is flip-chip bonded to the flip-chip pads, and a second IC die is back-side attached to the first IC die and ten wire-bonded to the wire-bondable pads. As a result, the flip-chip mounted first IC die is stacked with the second IC die in a simple, novel manner. | 12-25-2008 |
20080318353 | MICROELECTRONIC IMAGERS WITH OPTICAL DEVICES HAVING INTEGRAL REFERENCE FEATURES AND METHODS FOR MANUFACTURING SUCH MICROELECTRONIC IMAGERS - Microelectronic imager assemblies with optical devices having integral reference features and methods for assembling such microelectronic imagers is disclosed herein. In one embodiment, the imager assembly can include a workpiece with a substrate having a front side, a back side, and a plurality of imaging dies on and/or in the substrate. The imaging dies include image sensors, integrated circuitry operatively coupled to the image sensors, and external contacts electrically coupled to the integrated circuitry. The assembly also includes optics supports on the workpiece. The optics supports have openings aligned with corresponding image sensors and first interface features at reference locations relative to corresponding image sensors. The assembly further includes optical devices having optics elements and second interface features seated with corresponding first interface features to position the optics elements at a desired location relative to corresponding image sensors. | 12-25-2008 |
20090027076 | DEVICE AND METHOD FOR TESTING INTEGRATED CIRCUIT DICE IN AN INTEGRATED CIRCUIT MODULE - An IC module, such as a Multi-Chip Module (MCM), includes multiple IC dice, each having a test mode enable bond pad, such as an output enable pad. A fuse incorporated into the MCM's substrate connects each die's test mode enable bond pad to one of the MCM's no-connection (N/C) pins, and a resistor incorporated into the substrate connects the test mode enable bond pads to one of the MCM's ground pins. By applying a supply voltage to the test mode enable bond pads through the N/C pin, a test mode is initiated in the dice. Once testing is complete, the fuse may be blown, and a ground voltage applied to the test mode enable bond pads through the ground pins so the resistor disables the test mode in the dice and initiates an operational mode. As a result, dice packaged in IC modules may be tested after packaging. | 01-29-2009 |
20090155949 | MICROELECTRONIC IMAGERS WITH OPTICAL DEVICES AND METHODS OF MANUFACTURING SUCH MICROELECTRONIC IMAGERS - Microelectronic imager assemblies comprising a workpiece including a substrate and a plurality of imaging dies on and/or in the substrate. The substrate includes a front side and a back side, and the imaging dies comprise imaging sensors at the front side of the substrate and external contacts operatively coupled to the image sensors. The microelectronic imager assembly further comprises optics supports superimposed relative to the imaging dies. The optics supports can be directly on the substrate or on a cover over the substrate. Individual optics supports can have (a) an opening aligned with one of the image sensors, and (b) a bearing element at a reference distance from the image sensor. The microelectronic imager assembly can further include optical devices mounted or otherwise carried by the optics supports. | 06-18-2009 |
20090176362 | METHODS OF FORMING INTERCONNECTS IN A SEMICONDUCTOR STRUCTURE - A method of activating a metal structure on an intermediate semiconductor device structure toward metal plating. The method comprises providing an intermediate semiconductor device structure comprising at least one first metal structure and at least one second metal structure on a semiconductor substrate. The at least one first metal structure comprises at least one aluminum structure, at least one copper structure, or at least one structure comprising a mixture of aluminum and copper and the at least one second metal structure comprises at least one tungsten structure. One of the at least one first metal structure and the at least one second metal structure is activated toward metal plating without activating the other of the at least one first metal structure and the at least one second metal structure. An intermediate semiconductor device structure is also disclosed. | 07-09-2009 |
20110095429 | METHODS FOR FABRICATING AND FILLING CONDUCTIVE VIAS AND CONDUCTIVE VIAS SO FORMED - Methods for forming conductive vias include foiling one or more via holes in a substrate. The via holes may be formed with a single mask, with protective layers, bond pads, or other features of the substrate acting as hard masks in the event that a photomask is removed during etching processes. The via holes may be configured to facilitate adhesion of a dielectric coating that includes a low-K dielectric material to the surfaces thereof A barrier layer may be fowled over surfaces of each via hole. A base layer, which may comprise a seed material, may be formed to facilitate the subsequent, selective deposition of conductive material over the surfaces of the via hole. The resulting semiconductor devices, intermediate structures, and assemblies and electronic devices that include the semiconductor devices that result from these methods are also disclosed. | 04-28-2011 |
20110136336 | METHODS OF FORMING CONDUCTIVE VIAS - Methods of forming a conductive via may include forming a blind via hole partially through a substrate, forming an aluminum film on surfaces of the substrate, removing a first portion of the aluminum film from some surfaces, selectively depositing conductive material onto a second portion of the aluminum film, and exposing the blind via hole through a back side of the substrate. Methods of fabricating a conductive via may include forming at least one via hole through at least one unplated bond pad, forming a first adhesive over at least one surface of the at least one via hole, forming a dielectric over the first adhesive, forming a base layer over the dielectric and the at least one unplated bond pad, and plating nickel onto the base layer. | 06-09-2011 |
20130295766 | THROUGH-WAFER INTERCONNECTS FOR PHOTOIMAGER AND MEMORY WAFERS - A through-wafer interconnect for imager, memory and other integrated circuit applications is disclosed, thereby eliminating the need for wire bonding, making devices incorporating such interconnects stackable and enabling wafer level packaging for imager devices. Further, a smaller and more reliable die package is achieved and circuit parasitics (e.g., L and R) are reduced due to the reduced signal path lengths. | 11-07-2013 |
20140154879 | METHODS OF FORMING INTERCONNECTS AND SEMICONDUCTOR STRUCTURES - A method of activating a metal structure on an intermediate semiconductor device structure toward metal plating. The method comprises providing an intermediate semiconductor device structure comprising at least one first metal structure and at least one second metal structure on a semiconductor substrate. The at least one first metal structure comprises at least one aluminum structure, at least one copper structure, or at least one structure comprising a mixture of aluminum and copper and the at least one second metal structure comprises at least one tungsten structure. One of the at least one first metal structure and the at least one second metal structure is activated toward metal plating without activating the other of the at least one first metal structure and the at least one second metal structure. An intermediate semiconductor device structure is also disclosed. | 06-05-2014 |