| Intel Multi-core Curriculum Initiative › |
The maximum potential of multi-core systems to deliver great performance and expanded usages is unleashed only when software is designed to take advantage of the machine's full capabilities. With the entire industry moving towards the multi-core architercure, it has become imperative for the universities to introduce parallel programming in main stream education. To enable universities to successfully introduce real world multi-threading concepts, Intel Corporation has developed a program to provide tools, industry expertise and training modules for universities to use in their classrooms.
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| Parallel Computer Architecture and Programming Example Curriculum › |
This course provides a deep understanding of the principles and engineering tradeoffs involved in designing modern parallel computers (aka "multiprocessors" and "multicore"), as well as the programming techniques to effectively utilize these machines.
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| Signal Integrity Curriculum › |
Signal integrity refers to the communication between microprocessors and other high-speed computer and communications components. As the speed at which these components "talk" to each other increases, so does the demand for engineers with these skills.
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| Microelectronic Fabrication Curriculum › |
Today's fabrication technologies draw upon a wide variety of disciplines, and a diverse scientific and mathematical base. The Microelectronic Fabrication Curriculum is designed specifically to address these aspects of "process science" in an interdisciplinary way.
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| MicroElectronics Packaging Curriculum › |
"MicroElectronics assembly and packaging technology" or "Packaging" is a key element to Intel manufacturing and product development. This suite of courses reflects a two year masters program designed to provide the necessary multi-disciplinary background.
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| VLSI Curriculum › |
The VLSI Curriculum presents the complete coursework that may be considered when creating a VLSI program. The coursework is sequenced to show the interconnects between key areas such as analog design, digital design and overall architecture planning.
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| Network Processor Curriculum › |
The Networking & Network Processor Curriculum outlines the lessons and labs to develop an upper division networking course. The course sets up the framework for building networking skills and expertise and then illustrates this expertise.
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| Embedded Computing Curriculum › |
The Embedded Computing Curriculum not only provides in-depth materials to describe the scientific principles behind embedded systems, but also includes comprehensive lab projects to help students obtain hands-on experience in programming embedded systems.
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| Wireless Computing Curriculum › |
Wireless computing is becoming the standard for implementing computing and communication applications. This section presents two options on how wireless curriculum can be put into practice in existing computer science and electrical engineering programs.
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