The Sasaki Hook Is Not a [Static] Implicative Connective but Induces a Backward [in Time] Dynamic One That Assigns Causes

Coecke, Bob; Smets, Sonja

doi:10.1023/b:ijtp.0000048815.92983.6e

Cited by 27 publications

(21 citation statements)

References 48 publications

(104 reference statements)

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“…As observed in [22], the weakest precondition But the presence of classical negation ¬ gives us more expressive power. We can of course define the classical disjunction via de Morgan law: ϕ ∨ ψ := ¬(¬ϕ ∧ ¬ψ).…”

Section: The Logic Of Quantum Information Flowmentioning

confidence: 80%

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A Dynamic-Logical Perspective on Quantum Behavior

Baltag

Smets

2008

Stud Logica

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In this paper we show how recent concepts from Dynamic Logic, and in particular from Dynamic Epistemic logic, can be used to model and interpret quantum behavior. Our main thesis is that all the non-classical properties of quantum systems are explainable in terms of the non-classical flow of quantum information. We give a logical analysis of quantum measurements (formalized using modal operators) as triggers for quantum information flow, and we compare them with other logical operators previously used to model various forms of classical information flow: the "test" operator from Dynamic Logic, the "announcement" operator from Dynamic Epistemic Logic and the "revision" operator from Belief Revision theory. The main points stressed in our investigation are the following: (1) The perspective and the techniques of "logical dynamics" are useful for understanding quantum information flow. (2) Quantum mechanics does not require any modification of the classical laws of "static" propositional logic, but only a non-classical dynamics of information. (3) The main such non-classical feature is that, in a quantum world, all informationgathering actions have some ontic side-effects. (4) This ontic impact can affect in its turn the flow of information, leading to non-classical epistemic side-effects (e.g. a type of non-monotonicity) and to states of "objectively imperfect information". (5) Moreover, the ontic impact is non-local: an information-gathering action on one part of a quantum system can have ontic side-effects on other, far-away parts of the system.

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Section: The Logic Of Quantum Information Flowmentioning

confidence: 80%

“…by the actions that can be performed on the state. Within quantum logic, this dynamic turn found its way in [24,25,28] and this line of research was further developed by the Brussels school in quantum logic in [3,20,21,22,23,35].…”

Section: Introductionmentioning

confidence: 99%

A Dynamic-Logical Perspective on Quantum Behavior

Baltag

Smets

2008

Stud Logica

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“…with (− →Sasaki −) the (in)famous Sasaki hook [64]. In the light of the above argument, Pa now plays the role of how properties propagate in quantum measurements, while (a →Sasaki −)…”

Section: Measurement Among Other Processesmentioning

confidence: 97%

“…So in the Geneva School Mark II properties are a secondary notion emerging from considering experimental procedures on a given system A. The Geneva School Mark III emphasized the role of processes [66,87,43,55,64]. Faure, Moore and Piron were able to derive unitarity of quantum evolution by cleverly exploiting the definition of a physical property.…”

Section: Measurement Among Other Processesmentioning

confidence: 99%

A Universe of Processes and Some of Its Guises

Coecke

2011

Deep Beauty

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Our starting point is a particular 'canvas' aimed to 'draw' theories of physics, which has symmetric monoidal categories as its mathematical backbone. In this paper we consider the conceptual foundations for this canvas, and how these can then be converted into mathematical structure.With very little structural effort (i.e. in very abstract terms) and in a very short time span the categorical quantum mechanics (CQM) research program, initiated by Abramsky and the author in [6], has reproduced a surprisingly large fragment of quantum theory [45,171,180,61,57,62,49,3,63]. It also provides new insights both in quantum foundations and in quantum information, for example in [59,60,50,51,80,65,52,81], and has even resulted in automated reasoning software called quantomatic [76,77,75] which exploits the deductive power of CQM, which is indeed a categorical quantum logic [78].In this paper we complement the available material by not requiring prior knowledge of category theory, and by pointing at connections to previous and current developments in the foundations of physics.This research program is also in close synergy with developments elsewhere, for example in representation theory [73], quantum algebra [177], knot theory [188], topological quantum field theory [133] and several other areas. 1 arXiv:1009.3786v1 [quant-ph]

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“…Besides the quantum disjunction and negation, quantum logicians have studied the formal properties of the quantum implication (see, e.g., Kalmbach 1983;Hardegree 1975;Marsen et al 1981;Hardegree 1979;Coecke and Smets 2004;Smets 2001). Among the different candidates for a nice quantum implication that one can consider, it is important to note that the above Sasaki Hook has some similarities to the material implication of classical logic.…”

Section: Hilbert Space Semanticsmentioning

confidence: 99%

Modeling correlated information change: from conditional beliefs to quantum conditionals

Baltag

Smets

2017

Soft Comput

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In this paper, we propose a unified logical framework for representing and analyzing various forms of correlated information change. Our main thesis is that "logical dynamics," in the sense of van Benthem (Exploring logical dynamics. CSLI Publications, Stanford, 1996; Logical dynamics of information and interaction. Cambridge University Press, Cambridge, 2011), and in particular dynamic epistemic notions of conditional, as developed in Baltag and Smets (Electron Notes Theor Comput Sci 165:5-21, 2006a; Stud Log 89:185-209, 2008a; Texts in logic and games. Amsterdam University Press, Amsterdam, pp 9-58, 2008b), play a central role in understanding and modeling a wide range of apparently very different information-gathering phenomena which do have one specific feature in common, namely the very act of learning new information may directly change the reality that is being learned. On the one hand, we focus on the way in which an introspective agent changes her beliefs when learning new higher-order information, i.e., information that may refer to her own beliefs. On the other hand, we analyze situations in which an observer learns about a phenomenon by performing observations that may perturb the very phenomenon under study, as in the case of quantum measurements, or observations in social sciences, psychology and medicine. Our formal techniques are based on ideas Communicated by M.L. Dalla Chiara, R. Giuntini, E. Negri. from dynamic logic and on the modeling of "dynamic conditionals." We offer a semantics based on "test frames," i.e., Kripke frames labeled by propositional formulae which yields a unified setting for the two types of correlated information change under study. We show how this framework can be used to analyze the ontic and epistemic-informational aspects of quantum measurements and to compare them with other types of observation, testing, belief revision, counterfactual conditionals, etc.

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The Sasaki Hook Is Not a [Static] Implicative Connective but Induces a Backward [in Time] Dynamic One That Assigns Causes

Cited by 27 publications

References 48 publications

A Dynamic-Logical Perspective on Quantum Behavior

A Dynamic-Logical Perspective on Quantum Behavior

A Universe of Processes and Some of Its Guises

Modeling correlated information change: from conditional beliefs to quantum conditionals

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