دانلود کتاب Quantum Information Theory and the Foundations of Quantum Mechanics (Oxford Philosophical Monographs)

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Cover\nContents\n1 Introduction\n2 What is Information?\n 2.1 How to talk about information: Some simple ways\n 2.2 The Shannon Information and related concepts\n 2.2.1 Warming up\n 2.2.2 Formal development of the theory; and the definition of Informationt\n 2.2.3 Information and Uncertainty\n 2.2.4 More on the communication channel\n 2.2.5 Mutual informationt and flow\n 2.3 Alternative approaches: Dretske and Semantic Naturalism\n 2.3.1 Dretske’s information that\n 2.4 Summary\n3 Quantum Information Theory\n 3.1 Introduction\n 3.2 Bits and qubits\n 3.3 The no-cloning theorem\n 3.4 Entanglement-assisted communication\n 3.5 Quantum computers\n 3.6 What is quantum information?\n 3.6.1 Quantum sources: how much\n 3.6.2 Quantum sources: what\n 3.6.3 An objection: Jozsa’s argument\n 3.7 The worldliness of quantum information\n 3.7.1 Information and the physical\n 3.8 Summary\n4 Case Study: Teleportation\n 4.1 Introduction\n 4.2 The quantum teleportation protocol\n 4.2.1 Some information-theoretic aspects of teleportation\n 4.3 The puzzles of teleportation\n 4.4 Resolving (dissolving) the problem\n 4.4.1 The simulation fallacy\n 4.5 The teleportation process under di.erent interpretations\n 4.5.1 Collapse interpretations: Dirac/von Neumann, GRW\n 4.5.2 No collapse and no extra values: Everett\n 4.5.3 No collapse, but extra values: Bohm\n 4.5.4 Ensemble and statistical viewpoints\n 4.6 Concluding remarks\n5 The Deutsch–Hayden Approach: Nonlocality, Entanglement, and Information Flow\n 5.1 Introduction\n 5.2 The Deutsch–Hayden Picture\n 5.2.1 Locality claim (2): Contiguity\n 5.3 Assessing the Claims to Locality\n 5.3.1 The Conservative Interpretation\n 5.3.2 The Ontological Interpretation\n 5.4 Information and Information Flow\n 5.4.1 Whereabouts of information\n 5.4.2 Explaining informationt flow in teleportation: Locally accessible and inaccessible informationt\n 5.4.3 Assessing the claims for information flow\n 5.5 Conclusion\n6 Quantum Computation and the Church–Turing Hypothesis\n 6.1 Introduction\n 6.2 Quantum computation and containing information\n 6.3 The Turing Principle versus the Church–Turing Hypothesis\n 6.3.1 Non-Turing computability? The example of Malament– Hogarth spacetimes\n 6.3.2 Lessons\n 6.4 The Church–Turing Hypothesis as a constraint on physics?\n 6.5 Message\n7 Information and the Foundations of Quantum Mechanics: Preliminaries\n 7.1 Information Talk in Quantum Mechanics\n8 Some Information-Theoretic Approaches\n 8.1 Introduction\n 8.2 Zeilinger’s Foundational Principle\n 8.2.1 Word and world: Semantic ascent\n 8.2.2 Where next?\n 8.3 The Clifton–Bub–Halvorson characterization theorem\n 8.3.1 The setting\n 8.3.2 Some queries regarding the C*-algebraic starting point\n 8.3.3 Questions of Interpretation\n 8.4 Further Developments: Generalized Probability Theories\n 8.5 Conclusion\n9 Quantum Bayesianism 1: The Proposal\n 9.1 Introduction\n 9.2 Setting the Scene\n 9.2.1 An outline of the position\n 9.2.2 In more detail\n 9.2.3 From information to belief\n 9.2.4 Two hints\n 9.3 Not solipsism; and not instrumentalism, either\n 9.4 Summary: The virtues\n10 Quantum Bayesianism 2: Challenges\n 10.1 What’s the ontology?\n 10.1.1 Objectivity and the classical level\n 10.1.2 Quantum states for classical objects\n 10.2 Troubles with explanation\n 10.3 Subjective probabilities\n 10.3.1 A Quantum Bayesian Moore’s Paradox\n 10.3.2 The means/ends objection\n 10.4 Conclusions\n11 Conclusions\n A: A Review of the Quantum Formalism\n A.1 Hilbert Space and Linear Operators\n A.2 States and Measurement\n B: Generalized Uncertainty Measures: Uffink’s Axioms\n B.1 The Uncertainty Measures Ur(P,μ)\n B.2 Uniqueness arguments for the Shannon Information\n B.3 Majorization and entropic criteria for entanglement\nBibliography\nIndex\n A\n B\n C\n D\n E\n F\n G\n H\n I\n J\n K\n L\n M\n N\n O\n P\n Q\n R\n S\n T\n U\n V\n W\n Y\n Z