CPS Events
Research into Real World: KaTRIS activities at The GEAR
Abstract
Kajima, one of Japan’s oldest and largest construction companies, established its regional headquarters and innovation hub, The GEAR, in 2023. Before driving into the presentations on concrete-related technologies, Dr. Chae will provide an overview of The GEAR and the Kajima Technical Research Institute Singapore (KaTRIS) highlighting its mission, research frameworks, and strategic roles within Kajima Corporation.
Speaker Bios
Dr. Soungho Chae is currently a Deputy Executive General Manager of Kajima Technical Research Institute Singapore (KaTRIS). He completed his 1st Degree in Architectural Studies at Chungang University, Korea, followed by his Master of Science (MSc) Degree in 1992 and Doctor of Philosophy (PhD) Degree in 2003 from the WASEDA University, Japan. Thereafter, he worked as an Associate Professor at WASEDA University before joining Kajima, Japan in 2006. From 2018, he is based in Kajima, Singapore and serves as the Deputy General Manager at Kajima Technical Research Institute, Singapore (KaTRIS). His research focuses on building construction management, incorporating Information Communication Technology (ICT) and Robotics Technology (RT).
Dr. Yasuhiro Yokota is currently a chief research engineer and GM – Sustainable & Resilient Infrastructure Group in KaTRIS. He has pursued his undergraduate and master program in the Department of Civil Engineering at Kobe University, Japan. After graduating in 2006, he started to work at Kajima Technical Research Institute, Kajima Corporation in Japan. He has mainly worked in the field of tunnel engineering and rock mechanics related projects primarily working on new materials and Geo-sensing technics. Also, he experienced a large tunnel project in Japan as a technical manager for two years. After returning from the construction site in 2015, he moved to Singapore, for his PhD program at Nanyang Technological University (NTU). After being involved in the collaborative research between NTU and Kajima, he started to work at KaTRIS from 2019. He received many awards including the Rocha Medal 2021 by International Society of Rock Mechanics and Rock Engineering.
Tactile Sensing: At the Boundary Between Mechanical and Computational Intelligence in Robotic Grippers
Abstract
Robot grippers typically include mechanical intelligence (e.g., underactuation, compliance) or computational intelligence (e.g., fully actuated with a wide array of sensors). Next generation grippers and hands will require both intelligences to work in concert across applications with resilience and dexterity. This talk will introduce the concept of mechanical and computational intelligence co-design through example case studies that focus on the particular importance of embodied sensitivity as a feature of the co-design process. For example, the most recent work on the Smart Suction Cup, conducted largely by Dr. Jungpyo Lee, demonstrates how design decisions like the number of sensitive chambers influences the resultant robot arm controller as well as physical compliance and manufacturing feasibility and cost.
Speaker Bio
Dr. Hannah Stuart is an Associate Professor in the Department of Mechanical Engineering at the University of California at Berkeley. She received her BS in Mechanical Engineering at the George Washington University in 2011, and her MS and PhD in Mechanical Engineering at Stanford University in 2013 and 2018, respectively. Her research focuses on understanding the mechanics of physical interaction in order to better design systems for dexterous manipulation. Applications range from remote robotics to assistive orthotics. Recent awards include the NSF CAREER grant, NASA Early Career Faculty grant, Hellman Fellows Fund grant, and Johnson & Johnson Women in STEM2D grant. She is a Senior Member of IEEE.
Emergent Behavior, Robustness, and Adaptation in Heterogeneous Multi-Agent Systems
Abstract
Throughout the talk, we aim to convince you that enforcing consensus within a multi-agent system, despite agent heterogeneity, gives rise to new behaviors described by so-called blended dynamics. This phenomenon turns out to be useful in designing distributed algorithms. Understanding this process also provides insights into how robustness emerges within synchronized groups of agents. Finally, we will argue that enforced synchronization can also lead to the consensus of vector fields through parameter adaptation across the agents.
Speaker Bio
Hyungbo Shim received his B.S., M.S., and Ph.D. degrees from Seoul National University. He was a postdoctoral researcher at the University of California, Santa Barbara, and is currently a professor at Seoul National University. He has served as an associate editor for Automatica, IEEE Transactions on Automatic Control, and the International Journal of Robust and Nonlinear Control. He is a senior member of IEEE, an IFAC Distinguished Lecturer, and a member of the Korean Academy of Science and Technology. His research interests include stability analysis of nonlinear systems, observer design, disturbance observers, secure control systems, and synchronization in multi-agent systems.
Reinforcement Learning for Large-Scale Games
Abstract
This talk addresses the use of reinforcement learning in two-player zero-sum Markov games with finite but large state spaces, for which the goal is to find minimax policies with “modest”' computation. We use the qualifier “modest” to mean that we seek to certify policies as optimal without exploring the full state-space of the game.
The approach followed is strongly motivated by Q-learning, which was proposed in the late 1980s to extend the single-player dynamic programming principle to model-free reinforcement learning by eliminating the need for a known transition model. Extensions of Q-learning to two-player zero-sum games appeared shortly after. Since then, most of the work devoted to proving correctness of Q-learning relies on establishing that its iteration converges to a unique fixed-point of a Bellman-like equation, which generally requires exploring the full state-space.
We will see that, for zero-sum games, it is possible to construct provably correct optimal policies using algorithms inspired by Q-learning, without requiring convergence of the Q function over the whole state-space. In fact, the samples used to update the Q-function may not even explore the whole set of reachable states and, for certain classes of games, the fraction of explored states gets smaller and smaller as the size of the state-space increases.
Speaker Bio
João Pedro Hespanha received his Ph.D. degree in electrical engineering and applied science from Yale University, New Haven, Connecticut in 1998. From 1999 to 2001, he was Assistant Professor at the University of Southern California, Los Angeles. He moved to the University of California, Santa Barbara in 2002, where he currently holds a Distinguished Professor position with the Department of Electrical and Computer Engineering.
Dr. Hespanha is a Fellow of the International Federation of Automatic Control (IFAC) and of the IEEE. He was an IEEE distinguished lecturer from 2007 to 2013. His current research interests include multi-agent control systems; game theory; optimization; distributed control over communication networks (also known as networked control systems); stochastic modeling in biology; and network security. Additional information about his research and publications available at https://web.ece.ucsb.edu/~hespanha/.
Human Acceptance of Autonomous Systems
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.
