In mathematics and philosophy, Łukasiewicz logic (pronounced as /pl/) is a non-classical, many-valued logic. It was originally defined in the early 20th century by Jan Łukasiewicz as a three-valued modal logic;[1] it was later generalized to n-valued (for all finite n) as well as infinitely-many-valued (ℵ0-valued) variants, both propositional and first order.[2] The ℵ0-valued version was published in 1930 by Łukasiewicz and Alfred Tarski; consequently it is sometimes called the ŁukasiewiczTarski logic.[3] It belongs to the classes of t-norm fuzzy logics[4] and substructural logics.[5]
Łukasiewicz logic was motivated by Aristotle's suggestion that bivalent logic was not applicable to future contingents, e.g. the statement "There will be a sea battle tomorrow". In other words, statements about the future were neither true nor false, but an intermediate value could be assigned to them, to represent their possibility of becoming true in the future.
This article presents the Łukasiewicz(–Tarski) logic in its full generality, i.e. as an infinite-valued logic. For an elementary introduction to the three-valued instantiation Ł3, see three-valued logic.
The propositional connectives of Łukasiewicz logic are
→
\bot
\begin{align} \negA&=defA → \bot\\ A\veeB&=def(A → B) → B\\ A\wedgeB&=def\neg(\negA\vee\negB)\\ A\leftrightarrowB&=def(A → B)\wedge(B → A)\\ \top&=def\bot → \bot \end{align}
The
\vee
\wedge
In terms of substructural logics, there are also strong or multiplicative disjunction and conjunction connectives, although these are not part of Łukasiewicz's original presentation:
\begin{align} A ⊕ B&=def\negA → B\\ A ⊗ B&=def\neg(A → \negB) \end{align}
There are also defined modal operators, using the Tarskian Möglichkeit:
\begin{align} \DiamondA&=def\negA → A\\ \BoxA&=def\neg\Diamond\negA \end{align}
The original system of axioms for propositional infinite-valued Łukasiewicz logic used implication and negation as the primitive connectives, along with modus ponens:
\begin{align} A& → (B → A)\\ (A → B)& → ((B → C) → (A → C))\\ ((A → B) → B)& → ((B → A) → A)\\ (\negB → \negA)& → (A → B). \end{align}
Propositional infinite-valued Łukasiewicz logic can also be axiomatized by adding the following axioms to the axiomatic system of monoidal t-norm logic:
(A\wedgeB) → (A ⊗ (A → B))
\neg\negA → A.
That is, infinite-valued Łukasiewicz logic arises by adding the axiom of double negation to basic fuzzy logic (BL), or by adding the axiom of divisibility to the logic IMTL.
Finite-valued Łukasiewicz logics require additional axioms.
A hypersequent calculus for three-valued Łukasiewicz logic was introduced by Arnon Avron in 1991.[6]
Sequent calculi for finite and infinite-valued Łukasiewicz logics as an extension of linear logic were introduced by A. Prijatelj in 1994.[7] However, these are not cut-free systems.
Hypersequent calculi for Łukasiewicz logics were introduced by A. Ciabattoni et al in 1999.[8] However, these are not cut-free for
n>3
A labelled tableaux system was introduced by Nicola Olivetti in 2003.[9]
Infinite-valued Łukasiewicz logic is a real-valued logic in which sentences from sentential calculus may be assigned a truth value of not only 0 or 1 but also any real number in between (e.g. 0.25). Valuations have a recursive definition where:
w(\theta\circ\phi)=F\circ(w(\theta),w(\phi))
\circ,
w(\neg\theta)=F\neg(w(\theta)),
w\left(\overline{0}\right)=0
w\left(\overline{1}\right)=1,
and where the definitions of the operations hold as follows:
F → (x,y)=min\{1,1-x+y\}
F\leftrightarrow(x,y)=1-|x-y|
F\neg(x)=1-x
F\wedge(x,y)=min\{x,y\}
F\vee(x,y)=max\{x,y\}
F ⊗ (x,y)=max\{0,x+y-1\}
F ⊕ (x,y)=min\{1,x+y\}.
F\Diamond(x)=min\{1,2x\},F\Box(x)=max\{0,2x-1\}
The truth function
F ⊗
F ⊕
F ⊗ (.5,.5)=0
F ⊕ (.5,.5)=1
T(p)=.5
T(p\wedgep)=T(\negp\wedge\negp)=0
T(p\veep)=T(\negp\vee\negp)=1
The truth function
F →
By definition, a formula is a tautology of infinite-valued Łukasiewicz logic if it evaluates to 1 under each valuation of propositional variables by real numbers in the interval [0, 1].
Using exactly the same valuation formulas as for real-valued semantics Łukasiewicz (1922) also defined (up to isomorphism) semantics over
The standard real-valued semantics determined by the Łukasiewicz t-norm is not the only possible semantics of Łukasiewicz logic. General algebraic semantics of propositional infinite-valued Łukasiewicz logic is formed by the class of all MV-algebras. The standard real-valued semantics is a special MV-algebra, called the standard MV-algebra.
Like other t-norm fuzzy logics, propositional infinite-valued Łukasiewicz logic enjoys completeness with respect to the class of all algebras for which the logic is sound (that is, MV-algebras) as well as with respect to only linear ones. This is expressed by the general, linear, and standard completeness theorems:[4]
The following conditions are equivalent:
A
A
A
A
Font, Rodriguez and Torrens introduced in 1984 the Wajsberg algebra as an alternative model for the infinite-valued Łukasiewicz logic.[10]
A 1940s attempt by Grigore Moisil to provide algebraic semantics for the n-valued Łukasiewicz logic by means of his Łukasiewicz–Moisil (LM) algebra (which Moisil called Łukasiewicz algebras) turned out to be an incorrect model for n ≥ 5. This issue was made public by Alan Rose in 1956. C. C. Chang's MV-algebra, which is a model for the ℵ0-valued (infinitely-many-valued) Łukasiewicz–Tarski logic, was published in 1958. For the axiomatically more complicated (finite) n-valued Łukasiewicz logics, suitable algebras were published in 1977 by Revaz Grigolia and called MVn-algebras.[11] MVn-algebras are a subclass of LMn-algebras, and the inclusion is strict for n ≥ 5.[12] In 1982 Roberto Cignoli published some additional constraints that added to LMn-algebras produce proper models for n-valued Łukasiewicz logic; Cignoli called his discovery proper Łukasiewicz algebras.[13]
Łukasiewicz logics are co-NP complete.[14]
Łukasiewicz logics can be seen as modal logics, a type of logic that addresses possibility,[15] using the defined operators,
\begin{align} \DiamondA&=def\negA → A\\ \BoxA&=def\neg\Diamond\negA\\ \end{align}
A third doubtful operator has been proposed,
\odotA=defA\leftrightarrow\negA
From these we can prove the following theorems, which are common axioms in many modal logics:
\begin{align} A& → \DiamondA\\ \BoxA& → A\\ A& → (A → \BoxA)\\ \Box(A → B)& → (\BoxA → \BoxB)\\ \Box(A → B)& → (\DiamondA → \DiamondB)\\ \end{align}
We can also prove distribution theorems on the strong connectives:
\begin{align} \Box(A ⊗ B)&\leftrightarrow\BoxA ⊗ \BoxB\\ \Diamond(A ⊕ B)&\leftrightarrow\DiamondA ⊕ \DiamondB\\ \Diamond(A ⊗ B)& → \DiamondA ⊗ \DiamondB\\ \BoxA ⊕ \BoxB& → \Box(A ⊕ B) \end{align}
However, the following distribution theorems also hold:
\begin{align} \BoxA\vee\BoxB&\leftrightarrow\Box(A\veeB)\\ \BoxA\wedge\BoxB&\leftrightarrow\Box(A\wedgeB)\\ \DiamondA\vee\DiamondB&\leftrightarrow\Diamond(A\veeB)\\ \DiamondA\wedge\DiamondB&\leftrightarrow\Diamond(A\wedgeB)\end{align}
In other words, if
\DiamondA\wedge\Diamond\negA
\Diamond(A\wedge\negA)
\DiamondA\wedge\Diamond\negA\leftrightarrow\odotA