Книга "Transitions from Digital Communications to Quantum Communications" посвящена переходу от цифровых квантовых коммуникаций, основанных на последних технологических достижениях в области фотонных кристаллов и их потенциальных применениях в системах. В первой части книги авторы представляют современное состояние развития квантовых коммуникаций, рассматривают квантовые вентили, такие как вентили Дойча, Тоффоли и Дедекинда, и исследуют возможность их использования в электронных схемах и системах. Также проводится сравнение квантовых схем с традиционными схемами, такими как FPGAs и DSPs. Кроме того, авторы рассматривают специфику квантовой коммуникации через понятия запутанности и состояний Белла, а также математические и физические аспекты квантовых оптических волокон и фотонных кристаллов, чтобы оптимизировать квантовые передачи. Во второй части книги авторы представляют шесть интегрированных приложений для квантовых коммуникаций, связывая эти концепции с практическими примерами.
In this book, the authors address the emerging field of quantum communications from a practical point of view, in light the most recent achievements in photonics, with a special emphasis on the applications that this technology offers. The book is structured as follows: - The first part finds its state of art within extensive quantum communications while reviewing key theory, such quantum gate designs together with state-of-the-art fabrication methods to evaluate the physical feasibility of these gates as standalone electronic circuitry in addition to comparing these circuits with other known solutions such as Field Programmable Gate Arrays and Digital Signal Processors. Furthermore, entanglement probability and Bell's states are examined together with the physical and mathematical aspects underlying quantum information and transmission over quantum optical cables and photonic crystal fibers in an effort to maximize quantum signal transmission. -The second part contains six examples of experimental realization of quantum information technologies that will make the impact on cyberspace possible. These included fiber connections and recent advances in quantum cryptography, up to distributed quantum sensing and cloud based quantum computing algorithms for devices based on ensemble quantum memories.
This book focuses on the transition toward quantum communication systems in light of present technological advancements on photonic circuits and potential applications. The contributors cover the current state-of-the-art in extensive quantum communication considering theory; a review of quantum gate implementations involving Deutsch, Toffoli, and Dedeking logic gates relative to feasibility as circuitry, as well as their realization within communication systems, including comparisons to standard circuits like Field Programmable Gate Array (FPGA) and Digital Signal Processing (DSP). The role of entanglement and Bell's states in quantum communication is delineated alongside technical aspects related to quantum optical fiber and photonic crystal alternatives for optimized signal transmissions. Applications pertinent to real-world issues synthesize these ideas in the final section of the book through six integrated case studies in practical quantum communication.
Электронная Книга «Transitions from Digital Communications to Quantum Communications» написана автором Malek Benslama в году.
Минимальный возраст читателя: 0
Язык: Английский
ISBN: 9781119330196
Описание книги от Malek Benslama
This book addresses the move towards quantum communications, in light of the recent technological developments on photonic crystals and their potential applications in systems. The authors present the state of the art on extensive quantum communications, the first part of the book being dedicated to the relevant theory; quantum gates such as Deutsch gates, Toffoli gates and Dedekind gates are reviewed with regards to their feasibility as electronic circuits and their implementation in systems, and a comparison is performed in parallel with conventional circuits such as FPGAs and DSPs. The specifics of quantum communication are also revealed through the entanglement and Bell states, and mathematical and physical aspects of quantum optical fibers and photonic crystals are considered in order to optimize the quantum transmissions. These concepts are linked with relevant, practical examples in the second part of the book, which presents six integrated applications for quantum communications.
