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Many Sorted First-order Logic

Many Sorted First-order Logic. Student: Liuxing Kan Instructor: William Farmer Dept. of Computing and Software McMaster University, Hamilton, CA. Contents. Introduction: What is many sorted FOL Syntax: Languages of many sorted FOL Syntax: Terms and Formulas of many sorted FOL

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Many Sorted First-order Logic

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  1. Many Sorted First-order Logic Student: Liuxing Kan Instructor: William Farmer Dept. of Computing and Software McMaster University, Hamilton, CA

  2. Contents • Introduction: What is many sorted FOL • Syntax: Languages of many sorted FOL • Syntax: Terms and Formulas of many sorted FOL • Example of Many-sorted FOL Semantics • Semantics of many sorted FOL • Proof Theory of Many-sorted FOL • The completeness of many-sorted logic • Reduction many-sorted logic to one-sorted logic • Reference

  3. Introduction: what is many-sorted FOL • Sometimes people want to express properties of structures of different sorts (types). There are plenty of examples of subjects where the semantics of formulas are many-sorted structures. For instance, in geometry, to take a simple and ancient example, we use universes of pointes, lines, angles, triangles, rectangles, polygons, etc. • By adding to the formalism of first-order logic the notion ofsort, we can obtain a flexible and convenient logic called many-sorted first order logic, which has the same properties as first order logic. • In contrast to FOL, in many-sorted FOL, the arguments of function and predicate symbols may have different sorts, and constant and function symbols also have some sorts. • Uses of many-sorted logic: abstract data types, semantics and program verification, definition of programming languages, algebras for logic, databases, dynamic logic, semantics of natural languages, computer-aided problem solving, knowledge representation of design, logic programming and automated deduction.

  4. Syntax: Languages of many sorted FOL • In contrast to standard first-order languages, in many-sorted first order languages, the argument of function and predicate symbols may have different sorts, and constant and function symbols also have some sort. Technically, this means that a many-sorted alphabet is a many-sorted ranked alphabet. (An S-ranked alphabet is pair(Σ,r) consisting of a set Σ together with a function r: Σ→S*×S assigning a rank (u, s) to each symbol f in Σ ) • Alphabet of many-sorted first order language: - S U {bool} of sorts containing the special sort bool - Connectives: Λ,ν,→,↔, all of rank (bool.bool, bool), ¬(not) of rank (bool, bool), ┴(of rank (e, bool)); - Quantifiers: ∀ , ∃ ,each of rank (bool, bool); - Variables: a countable set Vs={X0,X1,X2…}, each variable Xi being of rank (e,s). - Auxiliary symbols: “(” and “)” - Equality symbol ≒, of rank (ss, bool)

  5. Syntax: Languages of many sorted FOL • A (S U {bool})-ranked alphabet L of nonlogical symbols consisting of: - FS: function symbols, FS→S+×S, assigning a pair r(f)=(u,s) called rank to every function symbol f. The string u is called the arity of f, and the symbol s is the sort of f. - CSs: constants, For every sort s∈S, a set CSs of symbols c0,c1,…, each of rank (e,s). The family of sets CSs is denoted by CS -PS: predicate symbols, A set PS of symbols P0,P1,…,and a rank function r:PS→S+×{bool}, assigning a pair r(P)=(u,bool) called rank to each predicate symbol P. The string u is called the arity of P. If u=e, P is a propositional letter. • It is assumed that the sets Vs, FS, CSs, and PS are disjoint for all s∈S. We will refer to a many-sorted first order language with set of nonlogical symbols L as the language L. Many-sorted first order languages obtained by omitting the equality symbol are referred to as many-sorted first order languages without equality.

  6. Syntax: Terms and Formulas of M-S FOL • Let L=(CS,FS,PS) be a language of many sorted FOL • Terms atomic formulas of L are defined as follows: - Each constant and each variable of sort sis a term of L. - If t1,…,tn are terms, each ti of sort ui, and f is function symbol of rank (u1…un,s), then ft1…tn is a term of sort s - Each propositional letter is an atomic formula. - If t1,…,tn are terms, each ti of sort ui, and P is a predicate symbol of arity u1…un, then Pt1…tn is an atomic formula: • Formulas are defined as follows: - Every atomic formula is a formula - For any two formula A and B, (AΛB), (AνB), (A →B), (A↔B ), ¬A are also formula - For any variable xi of sort s and any formula A, ∀sxiA and ∃sxiA are also formulas

  7. Example of Many-sorted FOL • Let L be following many-sorted first order language for stacks, where S={stack, integer}, CSinterger={0}, CSstack={Λ}, FS={Succ, +, *, push, pop, top}, and PS={<} The rank functions are given by: - r(succ)=(integer, integer); - r(+)=r(*)=(integer.integer, integer); - r(push)=(stack.integer, stack); - r(pop)=(stack, stack); - r(top)=(stack, integer); - r(<)=(integer.integer, bool); Then, the following are terms: Succ 0 top push Λ Succ 0 The following are formulas: < 0 Succ 0 ∀integerx ∀stacky≒stack pop push y x y

  8. Semantics of many sorted FOL • Many-sorted first order structures - First, let define many-sorted Σ-algebra A is a pair <A,I>, where A=(As)s∈S is an S-indexed family of nonempty sets, each As being called a carrier of sort s, and I is an interpretation function assigning functions to the function symbols. - Give a many-sorted first order language L, a many-sorted L-structure M is a many-sorted L-algebra, such that the carrier of sort bool is the set BOOL={T,F} • Semantics of formulas Given a many-sorted L-structure M and an assignment v: V→M, the function tM: [V→M]→Ms defined by a term t of sort s is the function such that for every assignments v in [V→M], the value tM[v] is defined recursively as follows: 1. For a variable x of sort s, xM[v]=vs(x) 2. For a constant c, cM[v]= cM 3. Let t=f(t1…tn), then (ft1…tn)M[v]=fM((t1)M[v],…(tn)M[v]) 4. Let A=P(t1…tn), then (Pt1…tn)M[v]=PM((t1)M[v],…(tn)M[v]) 5. If (t1)M[v]=(t2)M[v] then (≒st1t2)M[v]=T otherwise F 6. Let * denotes {Λ, ν→, ↔}, then (A*B)M=*M(AM,BM) 7. (∀xi:sA)M[v]=T iff AM[v[xi:=m]]=T, for all m∈Ms and (∃ xi:sA)M[v]=T iff AM[v[xi:=m]]=T, for some m∈Ms

  9. Proof Theory of Many-sorted FOL • Gentzen System G for Many-sorted Languages Without Equality • Gentzen System G= for languages With Equality

  10. The completeness of many-sorted logic • There are two degrees of completeness: Weak completeness: Each validity is a theorem. That is, |=Φimplies |-Φ for every formula Φ. Strong completeness: Every consequence of a set of formulas is also derivable from it. That is, for every set of formulas Γ and formulas Φ , when every Γ|=Φ then also Φ can be deduced from Γ. • Henkin’s theorem: Γ consistent → Γ has a model.

  11. Reduction to one-sorted logic • There is translation of many-sorted logic into one-sorted logic. Such a translation is described in Enderton, 1972, and you can read it for details. The essential idea to convert a many-sorted language L in to a one-sorted language L is to add domain predicate symbols Ds, one for each sort, and to modify quantified formulas recursively as follows: Every formula A of the form ∀x : sB (or ∃: sB) is converted to the formula A’ = ∀ x(Ds(x)→B’ ), where B’ is the result of converting B

  12. Many-Sorted Logic And its Applications, K.Meinke and J.V.Tucker Logic for Computer Science: Foundations of Automatic Theorem Proving, Jean Gallier Reference

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