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In this expanded edition of Quanta, Logic and Spacetime, the logical base is greatly broadened and quantum-computational aspects of the approach are brought to the fore. The first two parts of this edition may indeed be regarded as providing a self-contained and logic-based foundation for ? and an introduction to ? the enterprise known as quantum computing.The rest of the work takes on the task (as in the first edition) of computing from first principles certain dynamical expressions which turn out to compare favorably with the Lagrangian densities of the (massless) Standard Model, including gravity. The logic of this process is now subject to greater formal rigor than was possible in the first edition, and the central thesis ? that quantum physics at a fundamental level may itself be realized as a species of quantum computation ? is strongly underscored.
In this highly interesting monograph, a brief account of Finkelstein's approach to quantum theory and some of its ramifications is given. Specifically, his suggestion that some sort of quantum-set-like structure should underlie our macroscopic perception of spacetime is developed to the point where a fair slice of fundamental physics (for a massless world) may be formally derived in an elementary fashion from the ground up. In detail, a model of what Finkelstein has dubbed a “quantum net”, in conjunction with a carefully and extensively articulated correspondence principle, gives rise to the standard Lagrangians for: massless Dirac fermions, general relativity, and Yang-Mills fields for the gauge groups, U(1) x SU(2), and SU(3). These Lagrangians emerge replete with (Feynman) gauge-fixing terms and ghost fields, and a chiral breaking mechanism in the case of SU(2). The results are interpreted in the light of the Standard Model.
In this expanded edition of Quanta, Logic and Spacetime, the logical base is greatly broadened and quantum-computational aspects of the approach are brought to the fore. The first two parts of this edition may indeed be regarded as providing a self-contained and logic-based foundation for OCo and an introduction to OCo the enterprise known as quantum computing. The rest of the work takes on the task (as in the first edition) of computing from first principles certain dynamical expressions which turn out to compare favorably with the Lagrangian densities of the (massless) Standard Model, including gravity. The logic of this process is now subject to greater formal rigor than was possible in the first edition, and the central thesis OCo that quantum physics at a fundamental level may itself be realized as a species of quantum computation OCo is strongly underscored. Errata. Errata (159 KB). Sample Chapter(s). Foundations (207 KB). Contents: Preliminaries: Foundations: Quantum Sets; Group Duality, Coherence and Cyclic Actions; Computational Paradigms: Natural Deduction; Quantum Logic; The Computational Resources of Quantum Logic; The Plenum: A Quantum Net; Towards a Correspondence Principle for the Quantum Net; A Correspondence Principle for the Quantum Net; Dynamics I; Dynamics II; Comparisons, Interpretations and Speculations. Readership: Mathematicians and physicists."
This work is an attempt to describe various braches of mathematics and the analogies betwee them. Namely: 1) Symbolic Analogic 2) Lateral Algebraic Expressions 3) Calculus of Infin- ity Tensors Energy Number Synthesis 4) Perturbations in Waves of Calculus Structures (Group Theory of Calculus) 5) Algorithmic Formation of Symbols (Encoding Algorithms) The analogies between each of the branches (and most certainly other branches) of mathematics form, ”logic vectors.” Forming vector statements of logical analogies and semantic connections between the di↵erentiated branches of math- ematics is useful. It’s useful, because it gives us a linguistic notation from which we can derive other insights. These combined insights from the logical vector space connections yield a combination of Numeric Energy and the logic space. Thus, I have derived and notated many of the most useful tangent ideas from which even more correlations and connections ca be drawn. Using AI, these branches can be used to form even more connections through training of lan- guage engines on the derived models. Through the vector logic space and the discovery of new sheaf (Limbertwig), vast combinations of novel, mathematical statements are derived. This paves the way for an AGI that is not rigid, but flex- ible, like a Limbertwig. The Limbertwig sheaf is open, meaning it can receive other mathematical logic vectors with di↵erent designated meanings (of infi- nite or finite indicated elements). Furthermore, the articulation of these syntax forms evolves language away from imperative statements into a mathematically emotive space. Indeed, shown within, we see how the supramanifold of logic is shared with the supramanifold of space-time mathematically. Developing clean mathematical spaces can help meditation, thought pro- cess, acknowledgment of ideas spoken into that cognitive-spacetime and in turn, methods by which paradoxes can be resolved linguistically. This toolkit should be useful to all in the sciences as well as those bridging the humantities to mathematics. Using our memories as a toolkit to aggregate these ideas breaks down bound- aries between them in a new, exciting way. Merging philosophy and Quantum Mechanics together through the lens of symbolic analogies gives the tools to unravel this mystery of all mysteries. Mathematics thus exists as a bridge al- beit a complex one between the two disciplines, giving life to a composite art of problem-solving. Furthermore, mathematics yields to millions of other applications that are potentially limited only by our imagination. From massive data sets used for predictive analytics to emerging fields in medicine, mathematics is an energy and force at the center of possibilities. The power of mathematics to help manage life exists in its ability to shape and model the world in which we live and interact with one another. In conclusion, mathematics is a powerful tool that creates bridges and con- nections between many disciplines and serves as a powerful form of analytical data consumption. It provides language-rich bridges from which to assemble vast fields of theoretical investigations and create groundbreaking innovations. As we approach new horizons in the technology timeline, mathematics will con- tinue to be a powerful driver of creativity and progress.
Original, well-written work of interest Presents for the first time (physical) field theories written in sheaf-theoretic language Contains a wealth of minutely detailed, rigorous computations, ususally absent from standard physical treatments Author's mastery of the subject and the rigorous treatment of this text make it invaluable
Unified Field Mechanics, the topic of the 9th international symposium honoring noted French mathematical physicist Jean-Pierre Vigier cannot be considered highly speculative as a myopic critic might surmise. The 8th Vigier Symposium proceedings 'The Physics of Reality' should in fact be touted as a companion volume because of its dramatic theoretical Field Mechanics in additional dimensionality. Many still consider the Planck-scale zero-point field stochastic quantum foam as the 'basement of reality'. This could only be considered true under the limitations of the Copenhagen interpretation of quantum theory. As we enter the next regime of Unified Field Mechanics we now know that the energy-dependent Einstein-Minkowski manifold called spacetime has a finite radius beyond which a large-scale multiverse beckons. So far a battery of 14 experiments has been designed to falsify the model. When the 1st is successfully performed, a revolution in Natural Science will occur! This volume strengthens and expands the theoretical and experimental basis for that immanent new age.
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."
For correcting Einstein‘s shortcuts (singularities, dark energy, dark matter), General Relativity (GR) urgently needs a quantisation uniting it with Higgs‘ data and Feynman‘s virtual states by some discrete dynamics (shell model) which, in addition, also will consistently predict resonance masses, coupling constants, and decay widths without breaking any symmetry. This is accomplished by a quantum gravity (QG) based on Dirac. Nature is considered as a static tensor made of discrete quanta subjected to a hyperbolical imbalance, embedded in a Matrioshka nesting providing dynamics and ToE-forces. With energy as the spin-like engine of time, motion just is varying observer positions in terms of a sequence of quantum leaps. Dark matter will split the matter left into valences (forces) and non-valences (dynamics) with the CPT-theorem generating horizons which create drastically transformed but equivalent dynamics beyond their causality barriers (event horizon, big bang). The cosmological constant yields Hubble‘s law, Feynman‘s propagators, and resonance widths. ToE reduces physics just to count numbers of quanta per quantum type. The mount-variant makes GR free of singularities and allows a complete geometrization of all ToE-forces according to Einstein’s GR. Kant’s “Prolegomena“ urgently needs an update. QG and ToE are axiomatic tensor models.
PaperbackIn 1905, when Albert Einstein introduced a new theory of time as space-time, otherwise known as âlocal timeâ, some philosophers considered it as (probably) his greatest discovery. The reason, evidently, is that time is more important than anything else except life itself. But what, essentially, is it? Einstein did not give us the philosophical interpretation of space-time. That is a task for the philosophers. Samuel K. K. Blankson, the Ghanaian philosopher, gives one of the most lucid and logical interpretations of what Einstein called âtime, pure and simpleâ. The strange and extremely technical phenomenon known as âtime dilationâ, which inspired Einstein to discover his special theory of relativity, is lucidly explained. The reader will find the answer simple and most surprising, and, it is hoped, satisfactory too.