Piscataway, New Jersey : , : IEEE, , [2015]

©2015

1-4673-7769-4

1 online resource (ix, 83 pages) : illustrations

004.67

Internet - Security measures

Internet of things

Inglese

Includes bibliographical references and index.

Session 1: Security and Privacy -- Session 2: Secure Protocols -- Session 3: Users and Privacy -- Session 4: Security Attacks and Threats -- Author Index.

The workshop will focus on contributions related to the security of mesh and machine to machine networks, secure software stacks running on ubiquitous network nodes, and algorithms used to provide secure end to end communication between nodes.

New York, New York : , : Apress, , [2023]

©2023

1-4842-8572-7

1 online resource (447 pages)

004.35

Swift (Computer program language)

User interfaces (Computer systems) - Design

Parallel processing (Electronic computers)

Inglese

Includes index.

Chapter 1: SwiftUI - A new Beginning -- Chapter 2: Getting Started with SwiftUI -- Chapter 3: SwiftUI Building Blocks -- Chapter 4: State Management -- Chapter 5: Displaying Data in Lists -- Chapter 6: Building Input Forms -- Chapter 7: Getting Started with Combine -- Chapter 8: Driving UI State with Combine- Chapter 9: Networking with Combine -- Chapter 10: Error Handling in Combine -- Chapter 11: Implementing Custom Combine Operators -- Chapter 12: Wrapping existing APIs in Combine (Firebase) -- Chapter 13: Combine Schedulers and SwiftUI -- Chapter 14: Getting Started with async-await -- Chapter 15: Using async-await in SwiftUI -- Chapter 16: Bringing it all together - SwiftUI, async-await, and Combine.

Develop UI-heavy applications more easily, faster, and error-free. Based on several enhancements to the Swift language, SwiftUI takes a declarative approach to building UIs. Instead of imperatively coding the UI, this book will show you how to describe how you want your UI to look. SwiftUI treats the UI as a function of its state, thereby making managing your app’s state a lot easier. Change the underlying data model to redraw all parts of the UI that are connected to that particular slice of data. Likewise, easily update the underlying data model from the UI elements your data model is connected to. Combine is Apple’s

Functional Reactive Programming framework. It complements SwiftUI and other frameworks, such as the networking APIs, in a natural way. Using Combine, you can subscribe to events and describe data processing in a way that is free of side effects. This allows for an easier implementation of event-driven applications. Using SwiftUI and Combine build more error-free apps in a shorter amount of time, targeting all of Apple’s platforms (iOS, iPadOS, watchOS, macOS, tvOS) with little to no overhead. By the end of the book you will have a solid understanding for architecting and implementing UI-heavy apps in a declarative and functional reactive way using SwiftUI, Combine, and async/await. You will: - Build simple and gradually more complex UIs in SwiftUI - Understand SwiftUI’s state management system - Work with Combine and Swift’s new async/await APIs to access the network and access other asynchronous APIs - Architect and structure modern applications on Apple platforms using SwiftUI, Combine, and async/await.

Dordrecht : , : Springer Netherlands : , : Imprint : Springer, , 2024

94-024-2254-4

1 online resource (224 pages)

NATO Science for Peace and Security Series B: Physics and Biophysics, , 1874-6535

HillebrandsBurkard

SerhaAlexander

MakarovDenys

ProkopenkoOleksandr

530.12

003.54

Quantum computing

Spintronics

Magnetism

Quantum Information

Inglese

1. Influence of strong electron–electron correlations on the electrical conduction and magnetic properties of substitutional alloys as advanced functional spintronic material (V.V. Lizunov, I.M. Melnyk, T.M. Radchenko, S.P. Repetsky, V.A. Tatarenko – G.V. Kurdyumov Institute for Metal Physics of the N.A.S. of Ukraine, Kyiv, Ukraine) -- 2. Engineered nanocolumnar magnetic films (María Garrido-Segovia, Lidia Martínez, Yves Huttel, Sašo Gyergyek, Ana Espinosa, Elena Navarro and José Miguel García-Martín – Departamento de Física de Materiales, Universidad Complutense de Madrid, Madrid, Spain; Instituto de Micro y Nanotecnología, Madrid, Spain; Instituto de Magnetismo Aplicado, Madrid, Spain; Instituto de Ciencia de Materiales de Madrid, Madrid, Spain; Department for Materials Synthesis, Jožef Stefan Institute, Ljubljana, Slovenia) -- 3. Mn-based perpendicular magnetic tunnel junctions (Andreas Kaidatzis – Institute of Nanoscience and Nanotechnology, N.C.S.R. “Demokritos”, Athens, Greece) -- 4. Longitudinal evolution of the magnetization in nanostructure (Ivan A. Yastremsky – Taras Shevchenko National University of Kyiv, Kyiv, Ukraine) -- 5. Controlling multimagnon interaction in magnetic nanodots and spintronic nanostructures (Roman Verba, Julia Kharlan, Vladyslav Borynskyi, Denys Slobodianiuk, Arezoo Etesamirad and Igor Barsukov – Institute of Magnetism, Kyiv, Ukraine; Institute of Spintronics and Quantum Information, Faculty of Physics, Adam Mickiewicz University, Poznań, Poland; Taras Shevchenko National University of Kyiv, Kyiv, Ukraine; Physics and Astronomy, University of California, Riverside, California, USA) -- 6. Domain wall automotion by cross section tailoring in ferromagnetic nanostripes (Dmytro Karakuts, Kostiantyn V. Yershov, Denis D. Sheka – Taras Shevchenko National University of Kyiv Kyiv, Ukraine; Leibniz-Institut fur Festkorper- und Werkstoffforschung, IFW Dresden, Dresden, Germany) -- 7. Supercritical propagation of nonlinear spin wave through an antiferromagnetic magnonic crystal (Oksana Yu. Gorobets, Volodymyr V. Kulish, Ihor A. Syzon, Daryna V. Provolovska – National Technical University of Ukraine «Igor Sikorsky Kyiv Polytechnic Institute», Kyiv, Ukraine) -- 8. Energy conversion and energy harvesting in spin diodes (Ivan Fantych, Volodymyr Prokopenko, Oleksandr Prokopenko – Taras Shevchenko National University of Kyiv, Kyiv, Ukraine) -- 9. Magnetic nanocomponents for frequency converting in quantum computing technologies (A.A. Girich, S.V. Nedukh, S.Yu. Polevoy, B. Rami, K.Yu. Sova, S.I. Tarapov, A.S. Vakula – O.Ya. Usikov Institute for Radiophysics and Electronics of the N.A.S. of Ukraine, Kharkiv, Ukraine; Gebze Technical University, Gebze, Turkey) -- 10. Hybrid quantum systems for quantum transduction based on magnonic materials (S. Kazan, N.G. Saribas, M. Maksutoglu, S.Ç. Yorulmaz, E. Avinca, F. Yıldız, S.I. Tarapov, B. Rami – O.Ya. Usikov Institute for Radiophysics and Electronics of the N.A.S. of Ukraine, Kharkiv, Ukraine; V.N. Karazin Kharkiv National University, Kharkiv, Ukraine; Gebze Technical University, Kocaeli, Türkiye).

Macroscopic objects made of magnetic materials have been known to mankind for several thousand years and are widely used in various fields of human activity. With the development and practical implementation of microelectronics, and more recently nanoelectronics, it has become possible to develop and manufacture magnetic nanomaterials, dramatically expanding the scope of magnetics in modern technologies. Today, magnetic nanomaterials and

nanostructures are key components of advanced information technologies. They are widely used in eMobility, medicine, sensors, robotics, etc., and have significant potential for application in prospective smart wearables and human-machine interfaces. This volume outlines recent research in the field of functional magnetic and spintronic materials. Each of the 10 chapters in the volume is self-contained, allowing the topics to be explored independently of the material in other chapters. The book covers the entire “life cycle” of magnetic/spintronic nanomaterials: from theoretical and numerical studies of their properties (Ch. 1), fabrication and experimental study of film systems (Ch. 2), fabrication of nanostructures (Ch. 3), study of electromagnetic phenomena occurring in such nanostructures (Chs. 4-10), to the use of these nanostructures in new technologies, particularly in spintronic energy harvesting (Ch. 9) and quantum sensing (Ch. 10). Some of the contributions to this volume were presented as lectures and reports at the Advanced Research Workshop “Functional Spintronic Nanomaterials for Radiation Detection and Energy Harvesting” (25–27 September 2023, Kyiv, Ukraine), which was supported by the NATO Science for Peace and Security Programme.