Paraconsistent Quasi-Set Theory

Abstract

Paraconsistent logics are logics that can be used to base inconsistent but non-trivial systems. In paraconsistent set theories, we can quan- tify over sets that in standard set theories, if consistent, would lead to contradictions, such as the Russell set, R = fx : x =2 xg. Quasi-set theories are mathematical systems built for dealing with collections of indiscernible elements. The basic motivation for the development of quasi-set theories came from quantum physics, where indiscernible entities need to be considered. Usually, the way of dealing with indiscernible objects within clas- sical logic and mathematics is by restricting them to certain structures, in a way so that the relations and functions of the structure are not sufficient to individuate the objects; in other words, such structures are not rigid. In quantum physics, this idea appears when symmetry conditions are introduced, say by choosing symmetric and anti-symmetric functions in the relevant Hilbert spaces. But in standard mathematics, such as that built in Zermelo-Fraenkel set theory, any structure can be extended to a rigid structure. That means that, although we can deal with certain objects as they were indiscernible, we realize that from out- side of these structures these objects are no more indiscernible, for they can be individualized in the extended rigid structures: ZF is a theory of individuals, distinguishable objects. In quasi-set theory, it seems that there are structures that cannot be extended to rigid ones, so it seems that they provide a natural mathematical framework for expressing quantum facts without certain symmetry suppositions. There may be situations, however, in which we may need to deal with inconsistent bits of infor- mation in a quantum context, even if these informations are concerned with ways of speech. Furthermore, some authors think that superposi- tions may be understood in terms of paraconsistent logics, and even the notion of complementarity was already treated by such a means. This is, apparently, a nice motivation to try to merge these two frameworks. In this work, we develop the technical details, by basing our quasi-set theory in the paraconsistent system C1. We also elaborate a new hierarchy of paraconsistent calculi, the paraconsistent calculi with indiscernibility. For the finalities of this work, some philosophical questions are outlined, but this topic is left to a future work.

Other Versions

No versions found

Links

PhilArchive



    Upload a copy of this work     Papers currently archived: 99,666

External links

Setup an account with your affiliations in order to access resources via your University's proxy server

Through your library

  • Only published works are available at libraries.

Similar books and articles

Remarks on the Theory of Quasi-sets.Steven French & Décio Krause - 2010 - Studia Logica 95 (1-2):101 - 124.
A bridge between q-worlds.Benjamin Eva, Masanao Ozawa & Andreas Doering - 2021 - Review of Symbolic Logic 14 (2):447-486.
A Bridge Between Q-Worlds.Andreas Döring, E. V. A. Benjamin & Masanao Ozawa - 2021 - Review of Symbolic Logic 14 (2):447-486.

Analytics

Added to PP
2015-09-13

Downloads
33 (#625,150)

6 months
5 (#918,198)

Historical graph of downloads
How can I increase my downloads?

Author's Profile

Décio Krause
Federal University of Santa Catarina

Citations of this work

No citations found.

Add more citations

References found in this work

Understanding permutation symmetry.Steven French & Dean Rickles - 2002 - In Katherine Brading & Elena Castellani (eds.), Symmetries in Physics: Philosophical Reflections. New York: Cambridge University Press. pp. 212--38.
Structure, Individuality, and Quantum Gravity.John Stachel - 2006 - In Dean Rickles, Steven French & Juha T. Saatsi (eds.), The Structural Foundations of Quantum Gravity. Oxford, GB: Oxford University Press.

View all 7 references / Add more references