Alum Domenic Forte receives NSF CAREER Award

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Alumnus Domenic Forte (CE Ph.D. 2013) has received an NSF CAREER Award for “Transformative Approaches for Hardware Obfuscation Protection, Attacks, and Assessment.” The five-year, $400K grant will advance the state-of-the-art in hardware obfuscation for IP protection.

Forte is an assistant professor in the Department of Electrical and Computer Engineering at the University of Florida. At Maryland, Forte was advised by Professor Ankur Srivastava (ECE/ISR). Previously, he was an assistant professor in the ECE Department at the University of Connecticut. He received his Ph.D. in Electrical and Computer Engineering from the University of Maryland in 2013.

Forte's current research focuses on counterfeit detection and avoidance, hardware security primitives, hardware trojan detection and prevention, nanoscale integration challenges, reverse engineering and anti-reverse engineering, design tools, metrics, and rules for hardware security; and biometrics.

Abstract of the award
Electronic computing hardware forms the foundation of modern information systems and cyber infrastructure. However, the unavoidable involvement of untrusted parties who can insert malicious circuits (i.e., hardware Trojans), steal intellectual property (IP), and produce counterfeits have made hardware more vulnerable to cyber-attacks. National defense, welfare, and economic growth all suffer through 1) weaker security and quality of critical infrastructures; 2) substantial economic and reputational losses for IP owners; 3) increased revenue for terrorist groups, criminals, and adversarial nation states; and 4) lower incentive to innovate and develop new products. The objective of this project is to advance the state-of-the-art in hardware obfuscation for IP protection. Hardware obfuscation refers to transformation of a circuit design into one that is functionally equivalent to the original, but infeasible to reverse engineer and/or obtain unrestricted use without significant effort.

This project targets four major limitations associated with existing hardware obfuscation techniques: 1) Impractical overheads for real-world designs; 2) Susceptibility to attacks; 3) Poor scalability to large circuits of practical interest; and 4) lack of metrics and benchmarks in the research community to objectively compare different methods. Efficiency and scalability are being improved by developing novel circuit entropy metrics and holistic obfuscation algorithms that operate on decision diagrams. Outreach activities dedicated to obfuscation and awareness of IP piracy issues include creation of the first publically available benchmarks, conducting online global competitions, and generating new course materials, projects, and book. Through integration of these activities, measureable improvements in the attack resistance of obfuscated combinational and sequential designs are expected by project's end.

About the NSF CAREER Award
The NSF CAREER program fosters the career development of outstanding junior faculty, combining the support of research and education of the highest quality and in the broadest sense.

Published May 24, 2017