Apr 30 2014
The U.S. Department of Defense has awarded a $7.5 million grant to the University of Connecticut, University of Maryland, and Rice University to support research that will analyze and upgrade security protections for nanoscale computer hardware.
UConn's Center for Hardware Assurance, Security, and Engineering (CHASE), a national leader in computer hardware security research, will anchor the initiative, which involves 10 highly specialized researchers across three institutions.
"UConn's CHASE center houses some of the most advanced equipment available for nanoscale device characterization and testing," says UConn's Mark Tehranipoor, director of CHASE and the project's lead investigator. "Together with our colleagues from the University of Maryland and Rice University, we have created an exceptional team with unique capabilities in security analysis, nanoelectronics, counterfeit device detection, cryptography, and cyberattack countermeasures."
The development of micro computer processors and semiconductors over the past several decades has been driven by improvements in size and performance with little attention to security. As a result, there is an immediate need to identify and address the security challenges and vulnerabilities of existing and next-generation nanoscale devices within the semiconductor community, Tehranipoor says.
Nanoscale devices, many thousands of times smaller than the width of a human hair, are increasingly popular in the microelectronics industry and are performing vital functions supporting national security, commerce, energy, and transportation. Nanoscale chips are used in a wide variety of applications from air traffic control computers to medical devices to personal cell phones and the nation's electric grid and banking system.
"Just as performance and power are the primary focal points of early stage research in device development, this project intends to elevate security as a fundamental design parameter, thereby transforming the way new nanoscale devices are developed in the future," Tehranipoor says.
New technologies and other innovations generated by the research are expected to reduce the cost of development, enhance the security of military and space applications, and better protect the Department of Defense's electronic component supply chain from recycled, cloned, or defective computer hardware.
The highly competitive five-year multidisciplinary grant was awarded to the three universities by the Air Force Office of Scientific Research. UConn's CHASE, housing $3 million in high-end analysis and research equipment, will serve as the lead research lab. UConn's Nanoelectronics Laboratory and Nanofabrication Facility will support the project.
The University of Maryland's Cybersecurity Center, Institute for Systems Research, and Electrical and Computer Engineering Department will be assisting in the research. State-of-the-art equipment contained within Maryland's Embedded Systems and Hardware Security Lab and Wireless Sensors Lab will allow researchers to study the security vulnerabilities of current system designs and develop new methodologies for building nanoscale devices. Rice University's Adaptive Computing and Embedded Systems Laboratory will focus on the development of innovative nanoscale low-power, high performance processors and advanced security components such as unclonable functions and next generation random number generators. Rice researchers will also conduct security system analysis and explore cyberattack countermeasures.
"Nanoscale devices pose both opportunities and challenges," says University of Maryland Professor Ankur Srivastava. "Characterizing and modeling these devices, along with gaining an understanding of likely attacks and developing security properties to foil them, will enable us to create the kinds of devices that will meet the critical needs of the Department of Defense."
Rice Associate Professor of Electrical and Computer Engineering and of Computer Science Farinaz Koushanfar says: "Security has mostly been an afterthought for building computing devices. In conventional integrated circuit technology, once a design is realized and deployed, integrating security is difficult. We are truly excited to have the opportunity to investigate the security properties and vulnerabilities of next-generation nano-devices. We believe this work will lead to a paradigm shift incorporating security fully into the design and development of future generations of nanoscale computing hardware."