University of Illinois at Urbana-Champaign professor Carole Palmer says data curation is an important part of supporting and advancing research. “This is especially important in data-intensive science, where the power of discovery lies in applying computational approaches to large, aggregated data sets,” Palmer says. She says researchers need to plan around data-management requirements from the beginning of their projects, and to think in terms of a data set’s lifecycle. The biggest hurdles to overcome in collecting, curating, and managing data over a long period of time involve cost and labor. Even with the Internet and search engines, data stored online does not last nearly as long as data preserved in print. “We’re just beginning to do the research needed to guide how we build large-scale, multidisciplinary data repositories and collect and manage data in ways that add value and promote sharing and integration across laboratories, institutions, and disciplines,” Palmer says.
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University of Arkansas researchers have developed a new method for preventing the cloning of passive radio frequency identification (RFID) tags. The method prevents the production of counterfeit tags by focusing on one or more unique physical attributes of individual tags, instead of the information stored on the tags. “It is easy to clone an RFID tag by copying the contents of its memory and applying them to a new, counterfeit tag, which can then be attached to a counterfeit product–or person, in the case of these new e-passports,” says Arkansas professor Dale R. Thompson. “What we’ve developed is an electronic fingerprinting system to prevent this from happening.” The researchers determined that all RFID tags have a unique fingerprint due to variances in radio frequency and manufacturing. By using an algorithm that repeatedly sent reader-to-tag signals, the researchers found that radio frequencies in RFID tags ranged from 903 MHz to 927 MHz, and increased in increments of 2.4 megahertz. The measurements showed that each tag had a unique minimum power response at multiple radio frequencies, and that power responses were significantly different even in same-model tags. Thompson says the different minimal responses are just one of several unique physical characteristics that enabled them to create an electronic fingerprint to identify tags with a high probability of detecting counterfeit tags.

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Recent advancements in supercomputer design coupled with falling prices are breaking down the barriers that have traditionally surrounded computing-intensive research, which could give ordinary users with a novel idea the opportunity to explore its potential using powerful computers. Ninety percent of the world’s 500 fastest computers use standard microprocessors, which enable supercomputers to be built much more inexpensively. “I think this says that supercomputing technology is affordable,” says Advanced Micro Devices director Margaret Lewis. “We are kind of getting away from this ivory tower.” This possibility has inspired some of the world’s top computing experts to make valuable sources of information available, with the goal of filling supercomputers with scientific data and allowing anyone in the world with a PC to access these systems. “It’s a good call to arms,” says Silicon Graphics’ Mark Barrenechea. “The technology is there. The need is there. This could exponentially increase the amount of science done across the globe.” Sharing data and supercomputing resources could allow labs to accomplish far more than was previously possible. Argonne Leadership Computing Facility director Pete Beckman says shifting science research into the cloud democratizes science. Argonne, with funding from the U.S. Department of Energy, is working on Magellan, a project to explore the creation of a cloud-computing infrastructure that scientists around the world could use. Beckman says such a system would reduce the need for smaller universities and labs to spend money on their own computing infrastructure.

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Andy Johnson, a professor in the University of Illinois at Chicago’s Electronic Visualization Laboratory, is developing ultra-high-speed connections paired with high-definition video collaboration. Johnson says the technology is similar to commercial video phone services, but is more reliable, larger, and has a much clearer display. A stable, high-resolution video connection could change how people consult with doctors, auto mechanics diagnose cars, or businesspeople hold meetings, he says. The technology pairs life-sized display screens with near-instant Internet connections. “That gives us a much higher resolution interaction, and could make it much easier for remote groups to work together,” Johnson says. However, the system will require the United States to upgrade its Internet infrastructure with fiber-optic cables to increase access speeds.
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