Book contents
- Frontmatter
- Contents
- Preface
- Acronyms
- 1 Introduction
- 2 Questions and Answers
- 3 Classical Bits
- 4 Quantum Bits
- 5 Classical and Quantum Registers
- 6 Classical Register Mechanics
- 7 Quantum Register Dynamics
- 8 Partial Observations
- 9 Mixed States and POVMs
- 10 Double-Slit Experiments
- 11 Modules
- 12 Computerization and Computer Algebra
- 13 Interferometers
- 14 Quantum Eraser Experiments
- 15 Particle Decays
- 16 Nonlocality
- 17 Bell Inequalities
- 18 Change and Persistence
- 19 Temporal Correlations
- 20 The Franson Experiment
- 21 Self-intervening Networks
- 22 Separability and Entanglement
- 23 Causal Sets
- 24 Oscillators
- 25 Dynamical Theory of Observation
- 26 Conclusions
- Appendix
- References
- Index
Preface
Published online by Cambridge University Press: 24 November 2017
- Frontmatter
- Contents
- Preface
- Acronyms
- 1 Introduction
- 2 Questions and Answers
- 3 Classical Bits
- 4 Quantum Bits
- 5 Classical and Quantum Registers
- 6 Classical Register Mechanics
- 7 Quantum Register Dynamics
- 8 Partial Observations
- 9 Mixed States and POVMs
- 10 Double-Slit Experiments
- 11 Modules
- 12 Computerization and Computer Algebra
- 13 Interferometers
- 14 Quantum Eraser Experiments
- 15 Particle Decays
- 16 Nonlocality
- 17 Bell Inequalities
- 18 Change and Persistence
- 19 Temporal Correlations
- 20 The Franson Experiment
- 21 Self-intervening Networks
- 22 Separability and Entanglement
- 23 Causal Sets
- 24 Oscillators
- 25 Dynamical Theory of Observation
- 26 Conclusions
- Appendix
- References
- Index
Summary
In a routine optical telescope scan of a distant galaxy, astronomer Alice saw nothing unusual. Her radio astronomer colleague Bob, however, reported intense radio activity in that galaxy. Who had the true view of the galaxy?
This is the sort of question discussed in this book. If you said that Bob had the “true” view of the galaxy, you would be quite normal. Normal, in the sense of average, or typical, or even reasonable. But if you went on to read the rest of this book and understand its main message, you might then give a different answer to that question.
It is not a trick question, however. The “correct” answer is not “Alice has the true view of the galaxy.” Neither is it “Neither of them” nor is it “Both of them.”
This preface is not the place to discuss possible alternative answers to the above question; you should be able to work one out based on the principles discussed in the main text of this book. Although the question is easy to state, the answer we give in the last chapter is simple neither to explain nor to justify. It is best discussed using a lot of words and rather sophisticated mathematical models and technologies. These are introduced, developed, and applied after intensive preliminary discussions of the issues concerned.
Our answer is intimately bound up with the laws of observation as they pertain to quantum processes, the subject matter of this book. These laws are the rules that underpin modern, empirically based perceptions of physical reality (our term for the world of experience). It has taken over two thousand years of philosophical, natural philosophical, and empirical inquiry into the physical universe for some of these rules to be discovered, particularly the ones involving quantum processes. These latter have been understood for only the last hundred years or so, and what they mean is still an active subject of debate. The old question of how many angels can dance on the head of a pin is nothing compared with the question of what the wave function means in quantum mechanics.
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- Information
- Quantized Detector NetworksThe Theory of Observation, pp. xv - xviiPublisher: Cambridge University PressPrint publication year: 2017