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This book leverages an alternative interpretation of Quantum Theory explored in the Cosmology of Light book series, to suggest an alternative way to conceive of the fledgling field of Quantum Computing. The dynamics of superposition and entanglement are explored from the point of view of precipitating layers of reality so set up by light traveling at slower and slower speeds down to c, to in fact arrive at a different notion of quanta, of superposition, and of entanglement, that will suggest that reality at the quantum-level may be different from the view commonly held today. The very basis of modern-day quantum computing that relies on infinite number of superposed quantum states, on probability, on observable measurement that brings things into reality, is bought into question in the Light-centered Interpretation discussed in this book. In fact from the point of view of the latter interpretation superposition, entanglement, and reality take on a different meaning and the infinite processing power allegedly true of quantum states, like the new clothes in Han Christian Andersen’s The Emperor’s New Clothes simply does not exist in the manner in which it has been conceived. In the mathematical model of Light presented in this book all emergences are a result of the underlying fourfold properties of Light. Everything can be understood as a precise application of the core Light-Space-Time Emergence model. This is not unlike using binary representation of ones and zeros to code anything. The coding scheme here is a multi-layered fourfold symmetry, capable of modeling infinite diversity that captures functional to practical aspects that define any phenomenon or object. This scheme of coding lends itself to phenomena such as creation and emergence, and hence to a vast range of potential creative computation applications. Such a difference between construction, the focus of digital computing, and creation, the possible focus of quantum computing as elaborated in this book, is perhaps best captured by this image suggested by Albert Einstein: "Nature shows us only the tail of the lion. But there is no doubt in my mind that the lion belongs with it even if he cannot reveal himself to the eye all at once because of his huge dimension."
This book attempts to reveal something of the vastly different and fundamentally creative quality of computing that must accompany any computation involving the quantum-levels. To linearly project digital computing laurels manifest as increasing speeds and the ability to process vaster amounts of information, as the inevitable trajectory of quantum computing is perhaps, in the aphorism attributed to the Buddha, to look only at the finger and to miss the moon and the sky that it is pointing to. The cover figure highlights all that is being missed, summarized as an egg-like structure synonymous with the term ‘Hiranyagarbha’ in Sanskrit. This depicts the womb of creation, within which many layers and an upward-moving pattern of curves that themselves reflect the luminescence due to the constant superposition and entanglement inherent to the quantum computation that derives from a light-centered interpretation of quantum dynamics.
Winner of the Wolf Prize for his contribution to our understanding of the universe, Penrose takes on the question of whether artificial intelligence will ever approach the intricacy of the human mind. 144 illustrations.
Takes students and researchers on a tour through some of the deepest ideas of maths, computer science and physics.
Presents the author's thesis that consciousness, in its manifestation in the human quality of understanding, is doing something that mere computation cannot; and attempts to understand how such non-computational action might arise within scientifically comprehensive physical laws.
The multidisciplinary field of quantum computing strives to exploit some of the uncanny aspects of quantum mechanics to expand our computational horizons. Quantum Computing for Computer Scientists takes readers on a tour of this fascinating area of cutting-edge research. Written in an accessible yet rigorous fashion, this book employs ideas and techniques familiar to every student of computer science. The reader is not expected to have any advanced mathematics or physics background. After presenting the necessary prerequisites, the material is organized to look at different aspects of quantum computing from the specific standpoint of computer science. There are chapters on computer architecture, algorithms, programming languages, theoretical computer science, cryptography, information theory, and hardware. The text has step-by-step examples, more than two hundred exercises with solutions, and programming drills that bring the ideas of quantum computing alive for today's computer science students and researchers.
Automatic Quantum Computer Programming provides an introduction to quantum computing for non-physicists, as well as an introduction to genetic programming for non-computer-scientists. The book explores several ways in which genetic programming can support automatic quantum computer programming and presents detailed descriptions of specific techniques, along with several examples of their human-competitive performance on specific problems. Source code for the author’s QGAME quantum computer simulator is included as an appendix, and pointers to additional online resources furnish the reader with an array of tools for automatic quantum computer programming.
A thorough exposition of quantum computing and the underlying concepts of quantum physics, with explanations of the relevant mathematics and numerous examples. The combination of two of the twentieth century's most influential and revolutionary scientific theories, information theory and quantum mechanics, gave rise to a radically new view of computing and information. Quantum information processing explores the implications of using quantum mechanics instead of classical mechanics to model information and its processing. Quantum computing is not about changing the physical substrate on which computation is done from classical to quantum but about changing the notion of computation itself, at the most basic level. The fundamental unit of computation is no longer the bit but the quantum bit or qubit. This comprehensive introduction to the field offers a thorough exposition of quantum computing and the underlying concepts of quantum physics, explaining all the relevant mathematics and offering numerous examples. With its careful development of concepts and thorough explanations, the book makes quantum computing accessible to students and professionals in mathematics, computer science, and engineering. A reader with no prior knowledge of quantum physics (but with sufficient knowledge of linear algebra) will be able to gain a fluent understanding by working through the book.
This book addresses a broad community of physicists, engineers, computer scientists and industry professionals, as well as the general public, who are aware of the unprecedented media hype surrounding the supposedly imminent new era of quantum computing. The central argument of this book is that the feasibility of quantum computing in the physical world is extremely doubtful. The hypothetical quantum computer is not simply a quantum variant of the conventional digital computer, but rather a quantum extension of a classical analog computer operating with continuous parameters. In order to have a useful machine, the number of continuous parameters to control would have to be of such an astronomically large magnitude as to render the endeavor virtually infeasible. This viewpoint is based on the author’s expert understanding of the gargantuan challenges that would have to be overcome to ever make quantum computing a reality. Knowledge of secondary-school-level physics and math will be sufficient for understanding most of the text.
A Science journalist reveals the existence of the world's first quantum computer--created by a team of Silicon Valley researchers and able to simultaneously compute all possible solutions to a problem, making it the most powerful computer in the world.