Your search keyword '"*PROBABILITY in quantum mechanics"' showing total 5 results

1. How do classical and quantum probabilities differ?

Author

Gomatam, Ravi V.

Subjects

*PROBABILITY in quantum mechanics, *NUCLEAR physics experiments, *QUANTUM theory, *SUPERPOSITION principle (Physics), *SCIENTIFIC observation, *EMPIRICAL research

Abstract

I show that the classical coin tossing experiment involves two distinct definitions of probability, one ontological (the relative frequencies of initial deterministic states) and another empirical (the relative frequencies of observations). In quantum theory, I argue, only the latter definition can be invoked, since a single superposition state can give rise to multiple observation experiences. This difference explains why the present statistical quantum mechanics is an ontological dead end, despite its enormous pragmatic success. To get at the ontological content of quantum theory, I propose that the observations themselves can be interpreted on a different footing, without reference to determinate detector states. [ABSTRACT FROM AUTHOR]

Published

2012

2. On determinism, realism, non-locality and free will.

Author

Genovese, M. and Piacentini, F.

Subjects

*QUANTUM mechanics, *FREE will & determinism, *QUANTUM theory, *NUCLEAR physics experiments, *PROBABILITY in quantum mechanics

Abstract

We present an overview on some of the critical aspects of foundations of Quantum Mechanics, ranging from the concept of Realism to non-locality, random choice, macro-objectivation issue etc. [ABSTRACT FROM AUTHOR]

Published

2012

3. Possibility, probability and entanglement: Non-contextuality in modal quantum mechanics.

Author

Westmoreland, Michael D. and Schumacher, Benjamin

Subjects

*QUANTUM entanglement, *PROBABILITY in quantum mechanics, *HILBERT space, *QUANTUM theory, *MATHEMATICAL variables

Abstract

Modal quantum theory (MQT) is a simplified cousin of ordinary Hilbert space quantum theory. We show that two important theorems of actual quantum theory, the Kochen-Specker theorem excluding non-contextual hidden variables and the Conway-Kochen "free will theorem" about entangled systems, have direct analogues in MQT. The structure of possible measurement results for an entangled system in MQT cannot be represented by probability assignments satisfying the no-signaling principle, such as those given by ordinary quantum theory. [ABSTRACT FROM AUTHOR]

Published

2012

4. Double blinding-attack on entanglement-based quantum key distribution protocols.

Author

Adenier, Guillaume, Ohya, Masanori, Watanabe, Noboru, Basieva, Irina, and Khrennikov, Andrei Yu.

Subjects

*QUANTUM entanglement, *BLIND experiment, *PROBABILITY in quantum mechanics, *DETECTORS, *QUANTUM theory

Abstract

We propose a double blinding-attack on entangled-based quantum key distribution protocols. The principle of the attack is the same as in existing blinding attack except that instead of blinding the detectors on one side only, Eve is blinding the detectors of both Alice and Bob. In the BBM92 protocol, the attack allows Eve to get a full knowledge of the key and remain undetected even if Alice and Bob are using 100% efficient detectors. The attack can be easily extended to Ekert protocol, with an efficiency as high as 85.3%. [ABSTRACT FROM AUTHOR]

Published

2012

5. Probability in quantum theory from observer's mathematics point of view.

Author

Khots, Boris and Khots, Dmitriy

Subjects

*QUANTUM theory, *PROBABILITY in quantum mechanics, *OBSERVABILITY (Control theory), *HAMILTON'S equations, *QUANTUM communication, *PROBLEM solving

Abstract

This work considers the Hamilton equations of general relativity and quantum theory in a setting of arithmetic, algebra, and topology provided by Observer's Mathematics, see [1], [2], [3]. The probability appears automatically, without apriori assumptions. Certain results and communications pertaining to solutions of these problems are also provided. [ABSTRACT FROM AUTHOR]

Published

2012