Patent application number | Description | Published |
20120273782 | INTERPOSERS OF 3-DIMENSIONAL INTEGRATED CIRCUIT PACKAGE SYSTEMS AND METHODS OF DESIGNING THE SAME - An interposer of a package system includes a first probe pad disposed adjacent to a first surface of the interposer. A second probe pad is disposed adjacent to the first surface of the interposer. A first bump of a first dimension is disposed adjacent to the first surface of the interposer. The first bump is electrically coupled with the first probe pad. A second bump of the first dimension is disposed adjacent to the first surface of the interposer. The second bump is electrically coupled with the second probe pad. The second bump is electrically coupled with the first bump through a redistribution layer (RDL) of the interposer. | 11-01-2012 |
20130007692 | TOOL AND METHOD FOR MODELING INTERPOSER RC COUPLINGS - A method comprises analyzing front side conductive patterns and back side conductive patterns on a semiconductor interposer using a machine implemented RC extraction tool, and outputting data representing a plurality of respective RC nodes from the RC extraction tool to a tangible persistent machine readable storage medium. A substrate mesh model of the semiconductor interposer is generated, having a plurality of substrate mesh nodes. Each substrate mesh node is connected to adjacent ones of the plurality of substrate mesh nodes by respective substrate impedance elements. A set of inputs to a timing analysis tool is formed. The plurality of RC nodes are connected to ones of the plurality of substrate mesh nodes of the substrate mesh model. The set of inputs is stored in a tangible machine readable storage medium. | 01-03-2013 |
20130147505 | TEST PROBING STRUCTURE - A testing probe structure for wafer level testing semiconductor IC packaged devices under test (DUT). The structure includes a substrate, through substrate vias, a bump array formed on a first surface of the substrate for engaging a probe card, and at least one probing unit on a second surface of the substrate. The probing unit includes a conductive probe pad formed on one surface of the substrate and at least one microbump interconnected to the pad. The pads are electrically coupled to the bump array through the vias. Some embodiments include a plurality of microbumps associated with the pad which are configured to engage a mating array of microbumps on the DUT. In some embodiments, the DUT may be probed by applying test signals from a probe card through the bump and microbump arrays without direct probing of the DUT microbumps. | 06-13-2013 |
20130167095 | STACKED DIE INTERCONNECT VALIDATION - A system comprises a processor-implemented tool configured to generate a layout of an integrated circuit (IC) die. At least one non-transitory machine readable storage medium includes a first portion encoded with a first gate-level description of first and second circuit patterns to be formed on first and second integrated circuit (IC) dies, respectively, and a second portion encoded with a second gate level description of the first and second circuit patterns received from the processor implemented tool. The second gate level description includes power and ground ports, and the first gate level description does not include power and ground ports. A processor-implemented first verification module is provided for comparing the first and second gate level descriptions and outputting a verified second gate-level description of the first and second circuit patterns. | 06-27-2013 |
20140183692 | TECHNIQUES FOR FAST RESONANCE CONVERGENCE - Some methods provide an electronic design file, which includes an integrated circuit (IC) component that is operably coupled to a package component. The IC component and package component collectively form a resistor inductor capacitor (RLC) resonant circuit. The method also provides a damping component in the electronic design file. This damping component is configured to reduce a pre-resonant time during which energy exchanged in the RLC resonant circuit approaches a steady-state, and thereby speeds simulation time. | 07-03-2014 |
20140282305 | COMMON TEMPLATE FOR ELECTRONIC ARTICLE - One or more techniques or systems for incorporating a common template into a system on chip (SOC) design are provided herein. For example, a common template mask set is generated based on a first set of polygon positions from a first vendor and a second set of polygon positions from a second vendor. A third party creates a third party SOC design using a set of design rules generated based on the common template mask set. The common template is fabricated based on the third party SOC design using the common template mask set. Because the common template is formed using the common template mask set and because the common template mask set is based on polygon positions from both the first vendor and the second vendor, a part can be connected to the SOC regardless of whether the part is sourced from the first vendor or the second vendor. | 09-18-2014 |
20150154343 | SYSTEMS AND METHODS FOR DETERMINING EFFECTIVE CAPACITANCE TO FACILITATE A TIMING ANALYSIS - A method for timing analysis includes using the processor to determine an impedance profile of a coupling between at least a first inter-level via (ILV) and a a second ILV or a device, as a function of at least different frequency values. The impedance profile includes a plurality of impedance values corresponding to respective frequency values. An effective capacitance value corresponding to each respective impedance value is determined. At least one table is provided with respective impedance values and respective effective capacitance values for each respective frequency value. An RC extraction of a design layout of an ILV circuit is conducted using the populated table and based on determined effective capacitance values. | 06-04-2015 |
20150213182 | COMMON TEMPLATE FOR ELECTRONIC ARTICLE - One or more techniques or systems for incorporating a common template into a system on chip (SOC) design are provided herein. For example, a common template mask set is generated based on a first set of polygon positions from a first vendor and a second set of polygon positions from a second vendor. A third party creates a third party SOC design using a set of design rules generated based on the common template mask set. The common template is fabricated based on the third party SOC design using the common template mask set. Because the common template is formed using the common template mask set and because the common template mask set is based on polygon positions from both the first vendor and the second vendor, a part can be connected to the SOC regardless of whether the part is sourced from the first vendor or the second vendor. | 07-30-2015 |