Abstract

This seminar explores how society engages with autonomous transportation systems, focusing on automated vehicles and Advanced Air Mobility (AAM). Dr. Sina Nordhoff will present research on human acceptance, trust, and safety, emphasizing that public confidence and social readiness are essential alongside technological progress. Drawing on theoretical models, real-world applications, and extensive empirical data, including over 220 interviews and 40,000 surveys, Dr. Nordhoff will identify key factors shaping acceptance, such as socio-demographics, personality traits, perceived risks and benefits, and the effects of misuse or miscalibrated trust. The seminar will highlight how ethical considerations, societal norms, and regulatory frameworks influence deployment. Attendees will gain insight into how this work can guide policymakers, industry, and communities in ensuring responsible, equitable, and safe implementation. Dr. Nordhoff will also briefly discuss future research directions. 

Speaker Bio

Dr. Sina Nordhoff is a leading expert in the field of human factors and user acceptance of new and emerging transportation technologies. She holds a Ph.D. from Delft University of Technology and is affiliated with the University of California, Davis. Dr. Nordhoff specializes in electric vehicles and automated vehicles (AVs), focusing on how to responsibly integrate these innovations into society. Her research spans theoretical models, empirical studies, and real-world applications, involving over 220 interviews and 40,000 analyzed surveys. She has developed innovative frameworks to understand human acceptance, trust, and safety, addressing critical issues such as misuse, trust miscalibration, and cyber-physical attacks. Dr. Nordhoff's research is published in top-tier journals and has garnered significant attention from policymakers and industry leaders. Her work aims to inform the design, deployment, and regulation of these technologies to ensure they are safe, equitable, and socially beneficial. Dr. Nordhoff's current research agenda includes pioneering efforts in interdisciplinary theory development, safety assessment, and understanding cognitive measurements. Her overarching goal is to bridge the gap between technological advancements and societal well-being, creating a future where transportation benefits all members of society.

Abstract

Autonomous aerospace vehicles have applications in diverse fields like space exploration, disaster monitoring, infrastructure inspection, and transportation. However, in spite of several years of research on autonomy of aerospace vehicles, substantial challenges remain in achieving safe and reliable autonomy. The biggest challenges in integrating autonomous aerospace vehicles into human society have to do with dynamic uncertainties due to natural (environmental) effects and safety and reliability in interactions with humans. Recent advances in learning-based and data-enabled control and navigation have made it possible to deal with these challenges to some extent. However, most of these schemes lack nonlinear stability and robustness to external inputs or internal unknowns, which are needed to meet the stringent requirements of safety and reliability for autonomous aerospace vehicles. This talk presents some of my thoughts and ideas on safe autonomous operations of aerospace vehicles, based on how my research has handled these challenges. A key feature of this research is the stress on nonlinear stability and robustness of GNC algorithms for autonomous aerospace vehicles in the presence of actuator constraints, sensor and onboard processor capabilities, and dynamic (time-varying) uncertain inputs or disturbances. Future directions that include learning-based control for autonomous aerospace vehicles are also touched upon.

Speaker Bio

Amit Sanyal obtained the B.Tech. degree in Aerospace Engineering from the Indian Institute of Technology, Kanpur, in 1999. He completed his MS in Aerospace Engineering from Texas A&M University in 2001, where he received the Distinguished Graduate Student Master's Research Award. He obtained his Ph.D. in Aerospace Engineering and MS in Mathematics from the University of Michigan in 2004 and 2005, respectively, and was the recipient of an Engineering Academic Scholar Certificate. After his post-doctoral research at Arizona State University in 2005–2006, he joined the faculty in Mechanical Engineering at the University of Hawaii in 2007. He has been a faculty member in Mechanical and Aerospace Engineering at New Mexico State University (2010–2015), and is currently a faculty member in Mechanical and Aerospace Engineering at Syracuse University. He develops and applies techniques from geometric mechanics, nonlinear and geometric control, and continuous and discrete-time Lagrangian/Hamiltonian systems, to dynamics modeling, guidance, navigation, and control of unmanned and autonomous systems. He is an associate fellow of AIAA, a senior member of IEEE, and a member of ASME and SIAM. His research has been supported by NSF, NASA, and AFOSR, and he co-founded Akrobotix LLC, a robotics start-up company.