Abstract
We prove standard completeness for uninorm logic extended with knotted axioms. This is done following a proof-theoretical approach, based on the elimination of the density rule in suitable hypersequent calculi.
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Avron A (1987) A constructive analysis of RM. J Symb Log 52(4):939–951
Avron A (1991) Hypersequents, logical consequence and intermediate logics for concurrency. Ann Math Artif Intell 4:225–248
Baldi P, Ciabattoni A, Spendier L (2012) Standard completeness for extensions of MTL: an automated approach. In: Ong L, de Queiroz R (eds) Workshop on logic, language, information and computation (WoLLIC 2012). LNCS 7456. Springer, Heidelberg, pp 154–167
Ciabattoni A, Esteva F, Godo L (2002) T-norm based logics with n-contraction. Neural Netw World 12(5):441–452
Ciabattoni A, Galatos N, Terui K (2008) From axioms to analytic rules in nonclassical logics. In: IEEE symposium on logic in computer science (LICS 2008). IEEE, pp 229–240
Ciabattoni A, Galatos N, Terui K (2011) Macneille completions of FL-algebras. Algebra universalis 66(4):405–420
Ciabattoni A, Metcalfe G (2007) Density elimination and rational completeness for first-order logics. In: Symposium on logical foundations of computer science (LFCS 2007), LNCS 4514. pp 132–146
Ciabattoni A, Metcalfe G (2008) Density elimination. Theor Comput Sci 403(2–3):328–346
Cintula P, Esteva F, Gispert J, Godo L, Montagna F, Noguera C (2009) Distinguished algebraic semantics for t-norm based fuzzy logics: methods and algebraic equivalencies. Annals Pure Appl Logic 160(1):53–81
Esteva F, Gispert J, Godo L, Montagna F (2002) On the standard and rational completeness of some axiomatic extensions of the monoidal t-norm logic. Studia Logica 71(2):199–226
Gabbay DM, Metcalfe G (2007) Fuzzy logics based on [0, 1)-continuous uninorms. Arch Math Log 46(5–6):425–449
Galatos N, Jipsen P, Kowalski T, Ono H (2007) Residuated lattices: an algebraic glimpse at substructural logics: studies in logics and the foundations of mathematics. Elesevier, Amsterdam
Hájek P (1998) Metamathematics of fuzzy logic. Kluwer, Dordrecht
Horčík R (2011) Algebraic semantics: semilinear FL-algebras. In: Cintula P, Hájek P, Noguera C (eds) Handbook of mathematical fuzzy logic-volume 1, volume 37 of studies in logic. Mathematical logic and foundations. College Publications, London, pp 103–207
Hori R, Ono H, Schellinx H (1994) Extending intuitionistic linear logic with knotted structural rules. Notre Dame J Form Logic 35(2):219–242
Jenei S, Montagna F (2002) A proof of standard completeness for Esteva and Godo’s logic MTL. Studia Logica 70(2):183–192
Metcalfe G (2011) Proof theory for mathematical fuzzy logic. In: Cintula P, Hájek P, Noguera C (eds) Handbook of mathematical fuzzy logic-volume 1, volume 37of studies in logic. Mathematical logic and foundations. College Publications, London, pp 103–207
Metcalfe G, Montagna F (2007) Substructural fuzzy logics. J Symb Log 72(3):834–864
Metcalfe G, Olivetti N, Gabbay D (2008) Proof theory for fuzzy logics, volume 36 of Springer series in applied logic. Springer, New York
Takeuti G, Titani S (1984) Intuitionistic fuzzy logic and intuitionistic fuzzy set theory. J Symb Log 49(3):851–866
Wang SM (2012) Uninorm logic with the n-potency axiom. Fuzzy Sets Syst 205:116–126
Acknowledgments
I would like to thank the anonymous referees for their comments, which helped me to substantially improve the final form of the paper, and David Cerna, for linguistic advice. Furthermore, I would like to thank my supervisor Agata Ciabattoni for her guidance and advice throughout the whole preparation of this paper.
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Communicated by A. Ciabattoni.
Work supported by the project FWF START Y544-N23.
Appendix: Proof of the derivability of \(\alpha _1,\ldots , \alpha _k \rightarrow \alpha _1^k \vee \dots \vee \alpha _k^k\) in \(UL\)
Appendix: Proof of the derivability of \(\alpha _1,\ldots , \alpha _k \rightarrow \alpha _1^k \vee \dots \vee \alpha _k^k\) in \(UL\)
First, we show that \(\text {HUL}\) derives the hypersequent \(\alpha _1,\dots , \alpha _k\) \( \Rightarrow \alpha _1^k \, | \, \dots \, | \, \alpha _1, \dots , \alpha _{k} \Rightarrow \alpha _{k}^{k}\) . We proceed by induction on \(k\). For \(k=2\), we have
For the induction step, we assume to have a derivation \(d\) of \(\alpha _1,\dots , \alpha _{k-1} \Rightarrow \alpha _1^{k-1} \, | \, \dots \, | \, \alpha _1,\dots , \alpha _{k-1} \Rightarrow \alpha _{k-1}^{k-1}\) in \(\text {HUL}\). First, we show that for any \(\alpha _i\) with \(i=\{1,\dots , k-1\}\) we have a derivation \(d_i\) in \(\text {HUL}\) of the hypersequent \(\alpha _k,\alpha _i^{k-1} \Rightarrow \alpha _k^k \, | \, \alpha _k \Rightarrow \alpha _i\) .
Consider now the following derivation. For space reasons, we abbreviate the hypersequent \(\alpha _1,\dots , \alpha _{k-1} \Rightarrow \alpha _2^{k-1} \, | \, \dots \, | \, \alpha _1,\dots , \alpha _{k-1} \Rightarrow \alpha _{k-1}^{k-1}\) with \(H\).
Starting from the end-hypersequent above and repeating similar derivations for any of the \(d_i\), we eventually obtain the desired derivation of
From this, we get:
Finally, by the completeness of \(\text {HUL}\) with respect to \(\text {UL}\) (see Metcalfe and Montagna 2007), we have that \(\vdash _{UL} (\alpha _1,\ldots , \alpha _k) \rightarrow (\alpha _1^k \vee \dots \vee \alpha _k^k)\). This completes the proof.
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Baldi, P. A note on standard completeness for some extensions of uninorm logic. Soft Comput 18, 1463–1470 (2014). https://doi.org/10.1007/s00500-014-1265-1
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DOI: https://doi.org/10.1007/s00500-014-1265-1