Japaridze's Polymodal Logic
   HOME

TheInfoList



Click Here for Items Related To - Japaridze's Polymodal Logic
OR:
Japaridze's Polymodal Logic on:   [Wikipedia]   [Google]   [Amazon]

Japaridze's polymodal logic (GLP) is a system of
provability logic Provability logic is a modal logic, in which the box (or "necessity") operator is interpreted as 'it is provable that'. The point is to capture the notion of a proof predicate of a reasonably rich formal theory, such as Peano arithmetic. Examples ...
with infinitely many provability modalities. This system has played an important role in some applications of provability algebras in
proof theory Proof theory is a major branchAccording to , proof theory is one of four domains mathematical logic, together with model theory, axiomatic set theory, and recursion theory. consists of four corresponding parts, with part D being about "Proof The ...
, and has been extensively studied since the late 1980s. It is named after Giorgi Japaridze.


Language and axiomatization

The language of GLP extends that of the language of classical
propositional logic The propositional calculus is a branch of logic. It is also called propositional logic, statement logic, sentential calculus, sentential logic, or sometimes zeroth-order logic. Sometimes, it is called ''first-order'' propositional logic to contra ...
by including the infinite series of necessity operators. Their dual possibility operators are defined by . The axioms of GLP are all classical tautologies and all formulas of one of the following forms: * * * * And the rules of inference are: * From and conclude * From conclude


Provability semantics

Consider a sufficiently strong
first-order theory In mathematical logic, a theory (also called a formal theory) is a set of sentences in a formal language. In most scenarios a deductive system is first understood from context, giving rise to a formal system that combines the language with deduct ...
such as
Peano Arithmetic In mathematical logic, the Peano axioms (, ), also known as the Dedekind–Peano axioms or the Peano postulates, are axioms for the natural numbers presented by the 19th-century Italian mathematician Giuseppe Peano. These axioms have been used nea ...
. Define the series of theories as follows: * is * is the extension of through the additional axioms for each formula such that proves all of the formulas For each , let be a natural arithmetization of the predicate is the Gödel number of a sentence provable in . A ''realization'' is a function that sends each nonlogical atom of the language of GLP to a sentence of the language of . It extends to all formulas of the language of GLP by stipulating that commutes with the Boolean connectives, and that is , where stands for (the numeral for) the Gödel number of . An arithmetical completeness theoremG. Japaridze
"The polymodal logic of provability"
''Intensional Logics and Logical Structure of Theories''. Metsniereba, Tbilisi, 1988, pp. 16–48 (Russian). for GLP states that a formula is provable in GLP if and only if, for every interpretation , the sentence is provable in . The above understanding of the series of theories is not the only natural understanding yielding the soundness and completeness of GLP. For instance, each theory can be understood as augmented with all true sentences as additional axioms. George Boolos showed that GLP remains sound and complete with analysis (
second-order arithmetic In mathematical logic, second-order arithmetic is a collection of axiomatic systems that formalize the natural numbers and their subsets. It is an alternative to axiomatic set theory as a foundation of mathematics, foundation for much, but not all, ...
) in the role of the base theory .


Other semantics

GLP has been shown to be incomplete with respect to any class of
Kripke frame Kripke semantics (also known as relational semantics or frame semantics, and often confused with possible world semantics) is a formal semantics for non-classical logic systems created in the late 1950s and early 1960s by Saul Kripke and André J ...
s. A natural topological semantics of GLP interprets modalities as derivative operators of a polytopological space. Such spaces are called GLP-spaces whenever they satisfy all the axioms of GLP. GLP is complete with respect to the class of all GLP-spaces.L. Beklemishev and D. Gabelaia
"Topological completeness of provability logic GLP"
''Annals of Pure and Applied Logic'' 164 (2013), pp. 1201–1223.


Computational complexity

The problem of being a theorem of GLP is
PSPACE-complete In computational complexity theory, a decision problem is PSPACE-complete if it can be solved using an amount of memory that is polynomial in the input length (PSPACE, polynomial space) and if every other problem that can be solved in polynomial sp ...
. So is the same problem restricted to only variable-free formulas of GLP.F. Pakhomov
"On the complexity of the closed fragment of Japaridze's provability logic"
''Archive for Mathematical Logic'' 53 (2014), pp. 949–967.


History

GLP, under the name GP, was introduced by Giorgi Japaridze in his PhD thesis "Modal Logical Means of Investigating Provability" (
Moscow State University Moscow State University (MSU), officially M. V. Lomonosov Moscow State University,. is a public university, public research university in Moscow, Russia. The university includes 15 research institutes, 43 faculties, more than 300 departments, a ...
, 1986) and published two years later along with (a) the completeness theorem for GLP with respect to its provability interpretation (Beklemishev subsequently came up with a simpler proof of the same theorem) and (b) a proof that Kripke frames for GLP do not exist. Beklemishev also conducted a more extensive study of Kripke models for GLP. Topological models for GLP were studied by Beklemishev, Bezhanishvili, Icard and Gabelaia. The decidability of GLP in polynomial space was proven by I. Shapirovsky, and the PSPACE-hardness of its variable-free fragment was proven by F. Pakhomov. Among the most notable applications of GLP has been its use in proof-theoretically analyzing
Peano arithmetic In mathematical logic, the Peano axioms (, ), also known as the Dedekind–Peano axioms or the Peano postulates, are axioms for the natural numbers presented by the 19th-century Italian mathematician Giuseppe Peano. These axioms have been used nea ...
, elaborating a canonical way for recovering ordinal notation up to from the corresponding algebra, and constructing simple combinatorial independent statements (Beklemishev ). An extensive survey of GLP in the context of provability logics in general was given by George Boolos in his book ''The Logic of Provability''.G. Boolos,
The Logic of Provability
'. Cambridge University Press, 1993.


Literature

*L. Beklemishev
"Provability algebras and proof-theoretic ordinals, I"
''Annals of Pure and Applied Logic'' 128 (2004), pp. 103–123. *L. Beklemishev, J. Joosten and M. Vervoort
"A finitary treatment of the closed fragment of Japaridze's provability logic"
''Journal of Logic and Computation'' 15 (2005), No 4, pp. 447–463. *L. Beklemishev
"Kripke semantics for provability logic GLP"
''Annals of Pure and Applied Logic'' 161, 756–774 (2010). *L. Beklemishev, G. Bezhanishvili and T. Icar, "On topological models of GLP". ''Ways of proof theory, Ontos Mathematical Logic'', 2, eds. R. Schindler, Ontos Verlag, Frankfurt, 2010, pp. 133–153. *L. Beklemishev, "On the Craig interpolation and the fixed point properties of GLP". ''Proofs, Categories and Computations''. S. Feferman et al., eds., College Publications 2010. pp. 49–60. *L. Beklemishev
"Ordinal completeness of bimodal provability logic GLB"
''Lecture Notes in Computer Science'' 6618 (2011), pp. 1–15. *L. Beklemishev
"A simplified proof of arithmetical completeness theorem for provability logic GLP"
''Proceedings of the Steklov Institute of Mathematics'' 274 (2011), pp. 25–33. *L. Beklemishev and D. Gabelaia
"Topological completeness of provability logic GLP"
''Annals of Pure and Applied Logic'' 164 (2013), pp. 1201–1223. *G. Boolos
"The analytical completeness of Japaridze's polymodal logics"
''Annals of Pure and Applied Logic'' 61 (1993), pp. 95–111. *G. Boolos,
The Logic of Provability
' Cambridge University Press, 1993. *E.V. Dashkov, "On the positive fragment of the polymodal provability logic GLP". ''Mathematical Notes'' 2012; 91:318–333. *D. Fernandez-Duque and J.Joosten,
Well-orders in the transfinite Japaridze algebra
. ''Logic Journal of the IGPL'' 22 (2014), pp. 933–963. . . *G. Japaridze
"The polymodal logic of provability"
''Intensional Logics and Logical Structure of Theories''. Metsniereba, Tbilisi, 1988, pp. 16–48 (Russian). *F. Pakhomov
"On the complexity of the closed fragment of Japaridze's provability logic"
''Archive for Mathematical Logic'' 53 (2014), pp. 949–967. *D.S. Shamkanov
"Interpolation properties for provability logics GL and GLP"
''Proceedings of the Steklov Institute of Mathematics'' 274 (2011), pp. 303–316. *I. Shapirovsky
"PSPACE-decidability of Japaridze's polymodal logic"
''Advances in Modal Logic'' 7 (2008), pp. 289–304.


References

{{reflist Proof theory Provability logic