''Self-Healing'' Chips to Result from SRC Teamwork with National Science Foundation, University of Michigan; Even the Weak Semiconductors Survive; Advances Ensure Sustainability, Reliability of Computing Applications.SAN FRANCISCO -- Semiconductor Research Corporation (SRC (SouRCe) Contrast with DST, which is an abbreviation of "destination." ), the world's leading university-research consortium for semiconductors and related technologies, today announced the unprecedented development of chips that refuse to fail. Joint research by SRC, the National Science Foundation (NSF NSF - National Science Foundation ) and the University of Michigan (body, education) University of Michigan - A large cosmopolitan university in the Midwest USA. Over 50000 students are enrolled at the University of Michigan's three campuses. The students come from 50 states and over 100 foreign countries. will focus on analysis of the future landscape of hard silicon failures and their impact on non-trivial designs, such as microprocessors and their switch components. Success by the collaborative research effort of government, business and academia may provide the key to the future reliability of smaller semiconductor designs. "In this project, we'll go much further than before by designing chips that can diagnose when components wear out and heal themselves on the fly," said Sankar Basu, program director at NSF. "The bolstering of scientific underpinnings of computing is extremely important to the NSF. This issue of ensuring reliability is critical to the future of high-performance computing for even the most aggressive of applications." Current industry efforts to make chips more reliable, through redundancy and other traditional means, involve both higher costs and the sacrifice of the speed that consumers have come to expect in nearly all electronics, from servers to cell phones to transportation. In comparison, results from today's announcement of collaborative research are projected to provide defect-tolerant designs that will increase product lifetime through components that take longer to fail. Without innovative approaches to address in-field silicon failures, product lifetime will become dangerously short. "The aim is for chips that won't fail. That will be a first for the industry. The ramifications ramifications npl → Auswirkungen pl of increasing the reliability of the microprocessor in computing applications like planes, trains and automobiles is something we get very excited about," said William Joyner, SRC's director of Computer-Aided Design computer-aided design (CAD) or computer-aided design and drafting (CADD), form of automation that helps designers prepare drawings, specifications, parts lists, and other design-related elements using special graphics- and calculations-intensive and Test for the Global Research Collaboration (GRC GRC Greece (ISO Country code) GRC Glenn Research Center (NASA) GRC Governance, Risk and Compliance GRC Gendarmerie Royale du Canada (RCMP - Canada) GRC John H. ), a unit of the SRC that is responsible for narrowing the options for carrying CMOS (Complementary Metal Oxide Semiconductor) Pronounced "c-moss." The most widely used integrated circuit design. It is found in almost every electronic product from handheld devices to mainframes. to its ultimate limit. He is an IBM (International Business Machines Corporation, Armonk, NY, www.ibm.com) The world's largest computer company. IBM's product lines include the S/390 mainframes (zSeries), AS/400 midrange business systems (iSeries), RS/6000 workstations and servers (pSeries), Intel-based servers (xSeries) assignee assignee (assign) n. a person to whom property is transferred by sale or gift, particularly real property. (See: assign) ASSIGNEE. One to whom an assignment has been made. 2. to the consortium. "To continue the performance pace that billions of people have come to expect, we need more than technology advances. Sustained performance improvements require a critical coupling between technology and design." Reliability of complex systems has become increasingly difficult to model since more factors must be considered, from defects in circuits and wires on silicon, to failures in the software applications that the system runs. The research will entail the development of both straight-forward and intuitive silicon-failure models, and a fast, accurate reliability modeling infrastructure, that allow designers to better understand the reliable system design space and to evaluate the robustness of potential solutions. "The solution is not to build flawless chips, but architectures that can survive defects," said Dr. Todd Austin, associate professor of electrical engineering at University of Michigan and a former Intel design engineer. Dr. Valeria Bertacco, co-investigator and an assistant professor at the University of Michigan, adds, "We've not given up on making semiconductors always correct. Rather, we're facing up to the looming problem in the chip industry -- smaller switches and wires don't always work." Benefits of the research will serve chipmakers and end-users for communications, computing, aeronautics and aerospace applications, medical devices, automotive and consumer electronics, and a wide range of other applications that are dependent on silicon's correct performance. Today's announcement is the result of rigorous competition over many months under the SRC-GRC's Computer-Aided Design and Test Thrust. SRC and NSF selected the University of Michigan's team to fund for three years. SRC facilitates semiconductor research among its community of 23 companies and partners and 100 universities worldwide. About SRC As the pioneer of collaborative research for the semiconductor industry, SRC defines industry needs, invests in and manages the research that gives its members a competitive advantage in the dynamic global marketplace. SRC expands the industry knowledge base and attracts premier students to help innovate and transfer semiconductor technology to the commercial industry. Established in 1982, SRC is based in Research Triangle Park Research Triangle Park, research, business, medical, and educational complex situated in central North Carolina. It has an area of 6,900 acres (2,795 hectares) and is 8 × 2 mi (13 × 3 km) in size. Named for the triangle formed by Duke Univ. , NC, and drives long-term semiconductor research contracts on behalf of its participating members: Advanced Micro Devices, Inc., Applied Materials, Inc., Axcelis Technologies, Inc., Cadence Design Systems (company) Cadence Design Systems - A company that sells electronic design automation software and services. http://cadence.com/. See also Verilog. , Freescale Semiconductor, Inc., Hewlett-Packard Co., IBM Corp., Intel Corp., LSI LSI: see integrated circuit. (Large Scale Integration) Between 3,000 and 100,000 transistors on a chip. See SSI, MSI, VLSI and ULSI. Logic Corp., Mentor Graphics Corp., The Mitre Corp., Novellus Systems, Inc., Rohm and Haas Rohm and Haas Company (NYSE: ROH), a Philadelphia, Pennsylvania based company, manufactures miscellaneous materials. A Fortune 500 Company, Rohm and Haas employs more than 17,000 people in 27 countries. The annual sales revenue of Rohm and Haas stands at about USD 8.2 billion. Electronic Materials and Texas Instruments Corp. SRC also seeks to leverage funding from global government agencies. For more information, visit www.src.org. |
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