The 1st EWME is an International Tribune where: The Education in Microelectronics in 15 universities from 10 different countries are presented. The International Cooperation using the available multimedia is discussed. Pedagogical problems concerning the teaching of 'classical' microelectronics (technology, devices and CAD) as well as those concerning the sensors, microsystems and advanced materials are examined. Besides more general pedagogical views relative to the extended use of models, CAD and simulations are exposed.
Dear participant in the second European Workshop on Microelectronics Education, It is a pleasure to present you the Proceedings of the Second European Workshop on Microelectronics Education and to welcome you at the Workshop. The Organising Committee is very pleased that it has found several key persons, with highly appreciated levels of knowledge and expertise, willing to present Invited Contributions to this Workshop. We have striven for an interesting spread over important areas like the expected demands for educated engineers in the wide field of Microelectronics, and Microsystems, in European industry (and beyond!) and innovations in method and focus of our educational programmes. This is the second European Workshop in this area; the first one was held in Grenoble in France in the spring of 1996. It was the initiative of Georges Kamarinos, Nadine Guillemot and Bernard Courtois to organise this Workshop because they felt that Microelectronics was 'at a turning point' to become the core of the largest industry in the world and that this warranted a serious (re-)consideration of our educational imperatives. It is now two years since and their feeling has become reality: nobody doubts that by the year 2000 the microelecnonics industry will be the largest industrial sector. It is also obvious that because of that and because of the predicted shortfall of educated engineers we must continuously reconsider the quality of our educational approach.
In this book key contributions on developments and challenges in research and education on microelectronics, microsystems and related areas are published. Topics of interest include, but are not limited to: emerging fields in design and technology, new concepts in teaching, multimedia in microelectronics, industrial roadmaps and microelectronic education, curricula, nanoelectronics teaching, long distance education. The book is intended for academic education level and targets professors, researchers and PhDs involved in microelectronics and/or more generally, in electrical engineering, microsystems and material sciences. The 2004 edition of European Workshop on Microelectronics Education (EWME) is particularly focused on the interface between microelectronics and bio-medical sciences.
This is the third edition of the European Workshop on Microelectronics Education (EWME). A steady-state regime has now been reached. An international community of university teachers is constituted; they exchange their experience and their pedagogical tools. They discuss the best ways to transfer the rapidly changing techniques to their students, and to introduce them to the new physical and mathematical concepts and models for the innovative techniques, devices, circuits and design methods. The number of abstracts submitted to EWME 2000 (about one hundred) enabled the scientific committee to proceed to a clear selection. EWME is a European meeting. Indeed, authors from 20 different European countries contribute to this volume. Nevertheless, the participation of authors from Brazil, Canada, China, New Zealand, and USA, shows that the workshop gradually attains an international dimension. th The 20 century can be characterized as the "century of electron". The electron, as an elementary particle, was discovered by J.J. Thomson in 1897, and was rapidly used to transfer energy and information. Thanks to electron, universe and micro-cosmos could be explored. Electron became the omnipotent and omnipresent, almost immaterial, angel of our W orId. This was made possible thanks to electronics and, for the last 30 years, to microelectronics. Microelectronics not only modified and even radically transformed the industrial and the every-day landscapes, but it also led to the so-called "information revolution" with which begins the 21 st century.
"New Trends and Technologies in Computer-Aided Learning for Computer-Aided Design" contains the proceedings from the EduTech Workshop, an IFIP TC-10 Working Conference held in Perth, Australia. The workshop aimed to explore the interrelationship between computer-aided technology and computer-aided learning. Computation and communication technologies underpin work and development in many different areas. Among them, Computer-Aided Design of electronic systems and E-Learning technologies are two areas which are different but share many concerns. The design of CAD and E-Learning systems already touches on a number of parallels, such as system interoperability, user interfaces, standardization, EML-based formats, reusability aspects (of content or designs), and intellectual property rights. Furthermore, the teaching of Design Automation tools and methods is particularly amenable to a distant or blended learning setting, and implies the interconnection of typical CAD tools, such as simulators or synthesis tools, with e-learning tools.
A unique feature of this textbook is to provide a comprehensive introduction to the fundamental knowledge in embedded systems, with applications in cyber-physical systems and the Internet of things. It starts with an introduction to the field and a survey of specification models and languages for embedded and cyber-physical systems. It provides a brief overview of hardware devices used for such systems and presents the essentials of system software for embedded systems, including real-time operating systems. The author also discusses evaluation and validation techniques for embedded systems and provides an overview of techniques for mapping applications to execution platforms, including multi-core platforms. Embedded systems have to operate under tight constraints and, hence, the book also contains a selected set of optimization techniques, including software optimization techniques. The book closes with a brief survey on testing. This third edition has been updated and revised to reflect new trends and technologies, such as the importance of cyber-physical systems and the Internet of things, the evolution of single-core processors to multi-core processors, and the increased importance of energy efficiency and thermal issues.
This book contains the contributions presented at the 2nd international KES conference on Smart Education and Smart e-Learning, which took place in Sorrento, Italy, June 17-19, 2015. It contains a total of 45 peer-reviewed book chapters that are grouped into several parts: Part 1 - Smart Education, Part 2 – Smart Educational Technology, Part 3 – Smart e-Learning, Part 4 – Smart Professional Training and Teachers’ Education, and Part 5 – Smart Teaching and Training related Topics. This book can be a useful source of research data and valuable information for faculty, scholars, Ph.D. students, administrators, and practitioners - those who are interested in innovative areas of smart education and smart e-learning.
Human-Machine Interaction and IoT Applications for a Smarter World explores the futuristic trends at the cutting edge of study and research on Human-Machine Interaction (HMI), which is also known as Human-Computer Interface (HCI), and the Internet of Things (IoT) by featuring applications in a proficient, adaptable, and manageable way. It covers the mainstays of the IoT world through a thorough description of the present advancements, systems, and structures. This book: Discusses algorithms and design methodologies for the implementation of HMI based IoT systems. Covers real-time utility of IoT-based devices and systems. Provides human-machine interactive technologies and smart applications using IoT. Covers cyber-physical systems and IoT in HMI, using a blend of theoretical knowledge with a practical approach. It also covers important concepts including smart grid and energy consumption monitoring, smart vehicular and transportation systems, smart home automation, automatic identification systems, supervisory control and data acquisition systems, designing and integrating heterogeneous Human-Machine interactions, virtual and augmented reality, natural language processing, computer vision, and automatic speech recognition. This text will be useful for senior undergraduate, graduate students, and academic researchers in areas including electrical, electronics, and communications engineering, as well as computer science.
