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Advanced Packaging serves the semiconductor packaging, assembly and test industry. Strategically focused on emerging and leading-edge methods for manufacturing and use of advanced packages.
Nanolithography and Surface Microscopy with Electron Beams, Volume 231 merges two long-running serials, Advances in Electronics and Electron Physics and Advances in Optical and Electron Microscopy. The series features articles on the physics of electron devices (especially semiconductor devices), particle optics at high and low energies, microlithography, image science, digital image processing, electromagnetic wave propagation, electron microscopy, and the computing methods used in all these domains. Specific chapters cover Introduction to inverse problems in electron microscopy, Directional sinogram inpainting for limited angle tomography, Strain tomography of crystals, FISTA with adaptive discretization, Total variation discretization, and Reconstruction with a Gaussian Dictionary. - Provides the authority and expertise of leading contributors from an international board of authors - Presents the latest release in the Advances in Imaging and Electron Physics series
Over the past decade, China has quietly and methodically moved into a near-leadership position in artificial intelligence technologies on a global scale. Meanwhile, the United States has responded ineffectively, weighed down by politics, bureaucracy, and an absence of clear strategy. In the near future, wars will be fought not over land, but over data. Machines will quickly discover individualized treatments for diseases, and with the help of virtual reality, AI will inspect buildings that have not yet been built. With the rising interest in these technologies by both China and the U.S., who will emerge as the victor of this technological race? When AI Rules the World is an investigation and call to action into AI technologies for a nation that does not yet comprehend the full gravity of the AI revolution. The United States is losing the race for AI dominance, and the stakes couldn’t be higher.
This book presents the author's view of how the global semiconductor industry will evolve, based on recent megatrends not only in the industry but also in society, including the rapid proliferation of AI, the global semiconductor shortage, the rising importance of semiconductors in the value chain, and the movement to democratize semiconductors. It describes and explains major transformations taking place in the industry as a result, which necessitate significant changes not only to its technology but also its economic model and industrial structure. Finally, the book elaborates on the author's theory of super-evolution of semiconductors that will lead to the success of the industry in the emerging knowledge-based digital society. This book is a translation of an original German edition. The translation was done with the help of artificial intelligence (machine translation by the service DeepL.com).
This volume aims to document the most important worldwide accomplishments in converging knowledge and technology, including converging platforms, methods of convergence, societal implications, and governance in the last ten years. Convergence in knowledge, technology, and society is the accelerating, transformative interaction among seemingly distinct scientific disciplines, technologies, and communities to achieve mutual compatibility, synergism, and integration, and through this process to create added value for societal benefit. It is a movement that is recognized by scientists and thought leaders around the world as having the potential to provide far-reaching solutions to many of todayâ...
Focusing on the use of microlithography techniques in microelectronics manufacturing, this volume is one of a series addressing a rapidly growing field affecting the integrated circuit industry. New applications in such areas as sensors, actuators and biomedical devices, are described.
Silicon technology has developed along virtually one single line: reducing the minimal size of lithographic features. But has this taken us to the point of diminishing returns? Are we now at a turning point in the logical evolution of microelectronics? Some believe that the semiconductor microelectronics industry has matured: the research game is over (comparisons with the steel industry are being made). Others believe that qualitative progress in hardware technology will come roaring back, based on innovative research. This debate, spirited as it is, is reflected in the pages of Future Trends in Microelectronics, where such questions are discussed. What kind of research does the silicon industry need to continue its expansion? What is the technical limit to shrinking Si devices? Is there any economic sense in pursuing this limit? What are the most attractive applications of optoelectronic hybrid systems? Are there any green pastures beyond the traditional semiconductor technologies? Identifying the scenario for the future evolution of microelectronics will present a tremendous opportunity for constructive action today.