This book investigates the determinants of leadership in East Asia, emphasizing the significance of followership in the success and failure of leadership projects proposed by China, Japan, and the United States. While doing so, it answers a central question in the field of international relations: Why do potential leader countries succeed in obtaining potential followers in some instances, but fail to do so in other instances? Employing an inclusive leadership and societal approach, the book investigates how the leading countries motivate followership in East Asian economic and security dynamics. It analyzes how Chinese, Japanese and American leadership obtained acceptance from potential followers, focusing on the significance of domestic politics of potential follower countries in shaping their governmental preferences and generating followership. The book features empirical evidence in six case studies, covering topics such as the successful Chinese endeavor of South Korea joining the Chinese initiative for the Asian Infrastructure and Investment Bank (AIIB), the failed US attempt to prevent South Korea from doing so, the US's success to convince Japan to join the Trans-Pacific Partnership (TPP), the failed Japanese strive for winning South Korea's support for Japan's bid for a permanent seat at the UN Security Council (UNSC), the Chinese failure at obtaining the Philippines' backing of the Chinese aspirations in the South China Sea (SCS) during the Aquino Presidency, and, finally, the Chinese success one the same effort during the Duterte presidency. The book will appeal to students, scholars, and researchers of international relations interested in a better understanding of leadership determinants in East Asia, Global Power Shift, foreign policy, as well as East Asian economic and security dynamics.

Digital Microfluidic Biochips focuses on the automated design and production of microfluidic-based biochips for large-scale bioassays and safety-critical applications. Bridging areas of electronic design automation with microfluidic biochip research, the authors present a system-level design automation framework that addresses key issues in the design, analysis, and testing of digital microfluidic biochips.

The book describes a new generation of microfluidic biochips with more complex designs that offer dynamic reconfigurability, system scalability, system integration, and defect tolerance. Part I describes a unified design methodology that targets design optimization under resource constraints. Part II investigates cost-effective testing techniques for digital microfluidic biochips that include test resource optimization and fault detection while running normal bioassays. Part III focuses on different reconfiguration-based defect tolerance techniques designed to increase the yield and dependability of digital microfluidic biochips.

Expanding upon results from ongoing research on CAD for biochips at Duke University, this book presents new design methodologies that address some of the limitations in current full-custom design techniques. Digital Microfluidic Biochips is an essential resource for achieving the integration of microfluidic components in the next generation of system-on-chip and system-in-package designs.