Logic, Algebra and Truth Degrees 2008 September 8 to 11, Siena , Italy

On one-generated projective BL-algebrasAntonio Di Nola and Revaz GrigoliaUniversity of Salerno Tbilisi State UniversityDepartment of Mathematics Institute of Cybernetics and Informatics . Logic, Algebra and Truth Degrees2008 September 8 to 11, Siena , Italy

On one-generated projective BL-algebras LATD08Antonio Di Nola and Revaz Grigolia • BL-algebras are introduced by P. Hajek in [Metamathematics of fuzzy logic, Kluwer Academic Publishers, Dordrecht, 1998.] as an algebraic counterpart of the basic fuzzy propositional logic BL.

On one-generated projective BL-algebras LATD08Antonio Di Nola and Revaz Grigolia Basic fuzzy propositional logic is the logic of continuous t-norms. Formulas are built from propositional variables using connectives & (conjunction), → (implication) and truth constant 0 (denoting falsity). Negation ¬φ is defined as φ→0. Given a continuous t-norm * (and hence its residuum ) each evaluation e of propositional variables by truth degrees for [0,1] extends uniquely to the evaluation e*(φ) of each formula φ using * and  as truth functions of & and →. A formula φ is a t-tautology or standard BL-tautology if e*(φ) = 1 for each evaluation e and each continuous t-norm *.

On one-generated projective BL-algebras LATD08Antonio Di Nola and Revaz Grigolia • The following t-tautologies are taken as axioms of the logic BL: (A1) (φ → ψ) → ((ψ → χ) → (φ → χ)) (A2) (φ & ψ) → φ (A3) (φ & ψ) → (ψ & φ) (A4) (φ & (φ → ψ)) → (ψ & (ψ → φ)) (A5a) (φ → (ψ → χ)) → ((φ & ψ) → χ) (A5b) ((φ & ψ) → χ) → (φ → (ψ → χ)) (A6) ((φ → ψ) → χ) → (((ψ → φ) → χ) → χ) (A7) 0 → φ Modus ponens is the only inference rule: φ, φ → ψψ

On one-generated projective BL-algebras LATD08Antonio Di Nola and Revaz Grigolia BL-algebra(B; , , , ,0, 1)is a universal algebra of type(2,2,2,1,0,0)such that: • 1) (B; , ,0, 1) is a bounded distributive lattice; • 2) (B; , 1)is a commutativemonoid with identity: x  y = y  x, x (y  z) = (x  y)  z, x  1 = 1  x; • 3) (1) x (y  (x  y)) = x, (2) ((x  y)  x)  y = y, (3) (x  (x  y)) = 1, (4) ((x  z)  (z  (x _ y))) = 1, (5) (x  y)  z = (x  z)  (y  z), (6) x  y = x  (x  y), (7) x  y = ((x  y)  y)  ((y  x)  x), (8)x  y)  (y  x) = 1.

On one-generated projective BL-algebras LATD08Antonio Di Nola and Revaz Grigolia • BL-algebra B is named BL-chain if for every elements x, y B either x  y or y  x, where  is lattice order on B. • Let B1, B2 be BL-algebras, where B1 is BL-chain. Taking isomorphiccopies of the ones assume that 1B1= 0B2and (B1\ {1B1})  (B2\ {0B2}) = . • Let B1●B2 be the structure whose universe is B1B2 and x  y if (x, y B1and x 1 y) or (x, y B2 and x 2 y), or x B1and y B2 . Moreover, • x  y = x i y for x, y Bi, x  y = x for x B1and y B2 ; • x  y = 1B2 for x  y; • for x > y we put x  y = x i y if x, y Bi and • putx  y = y for x B2 and y B1\ B2.

On one-generated projective BL-algebras LATD08Antonio Di Nola and Revaz Grigolia According to the definition we have B1 B2 B1●B2

On one-generated projective BL-algebras LATD08Antonio Di Nola and Revaz Grigolia Proposition 1.B = B1●B2is aBL-algebra with 0B = 0B1 ; 1B = 1B2 and 1B1 = 0B2being non-extremal idempotent. Moreover, ifB1,B2areBL-chains, then B =B1●B2is BL-chain too.

On one-generated projective BL-algebras LATD08Antonio Di Nola and Revaz Grigolia • The variety BL of all BL-algebras is not locally finite and it is generatedby all finite BL-chains. • In addition, we have that the subvarieties of BL,which are generated by finite families of finite BL-chains, are locally finite.

On one-generated projective BL-algebras LATD08Antonio Di Nola and Revaz Grigolia • A BL-algebra is said to be an MV -algebra, if it satises the followingequation: x = x, where x = x  0. More precisely,

On one-generated projective BL-algebras LATD08Antonio Di Nola and Revaz Grigolia • An algebra A = (A;,,, 0,1), is said to be anMV-algebra, if it satises the following equations: (i) (x  y)  z = x  (y  z); (ii) x  y = y  x; (iii) x  0 = x; (iv) x  1 = 1; (v) 0 = 1; (vi) 1 = 0; (vii) x  y = (x y); (viii) (x  y)  y = (y  x)  x.

On one-generated projective BL-algebras LATD08Antonio Di Nola and Revaz Grigolia • Notice, that • x  y = x  y • x  y =(x  y)  y • x  y = (x y)

On one-generated projective BL-algebras LATD08Antonio Di Nola and Revaz Grigolia • Every MV -algebra has an underlying ordered structure x  y iff x  y = 1.

On one-generated projective BL-algebras LATD08Antonio Di Nola and Revaz Grigolia The following property holds in any MV -algebra: x y  x  y  x  y  x  y.

On one-generated projective BL-algebras LATD08Antonio Di Nola and Revaz Grigolia • The unit interval of real numbers [0,1] endowed with the following operations: x  y = min(1, x + y), x  y = max(0, x + y 1), x = 1  x, becomes an MV -algebra.

On one-generated projective BL-algebras LATD08Antonio Di Nola and Revaz Grigolia • It is well known that the MV -algebra S = ([0; 1];,,, 0,1) generate the variety MV of all MV -algebras, i. e. V(S) = MV. Let Q denote the set of rational numbers, for (0 )n we set Sn= (Sn; ,,, 0,1), where Sn= {0,1/n, … , n – 1/n}.

On one-generated projective BL-algebras LATD08Antonio Di Nola and Revaz Grigolia Let K be a variety. A algebra AK is said to be a freealgebrain K, if there exists a setA0 such that A0 generates A and every mapping f from A0 to any algebra BK is extended to a homomorphismh from A to B. In this case A0 is said to be the set of free generatorsofA. If the set of free gen

On one-generated projective BL-algebras LATD08Antonio Di Nola and Revaz Grigolia Also recall that an algebra AK is called projective, if for any B,CK, any epimorphism (that is an onto homomorphism )  : B C andany homomorphism  : A C, there exists a homomorphism  : A Bsuch that  = .

On one-generated projective BL-algebras LATD08Antonio Di Nola and Revaz Grigolia AB C   

On one-generated projective BL-algebras LATD08Antonio Di Nola and Revaz Grigolia McNaughton has proved that a function f : [0,1]m[0,1] has an MV polynomial representation q(x1 , . . ., xm) such that f = q iff f satisfies the following conditions:

On one-generated projective BL-algebras LATD08Antonio Di Nola and Revaz Grigolia • (i) f is continuous, • (ii) there exists a finite number of affine linear distinct polynomials1, . . ., s, each having the form j=bj+nj1x1+ … +njm where all b’s and n’s are integers such that for every(x1 , . . ., xm)[0, 1]mthere is j, 1 ≤ j ≤ s such that f(x1,…,xm)= j(x1,…,xm).

1 On one-generated projective BL-algebras LATD08Antonio Di Nola and Revaz Grigolia 1 Green line g (x ) = x ; brown line f (x ) = 1 – x.

On one-generated projective BL-algebras LATD08Antonio Di Nola and Revaz Grigolia 1 1 1 1 Min(g (x), f (x )) Max(g (x), f (x ))

On one-generated projective BL-algebras LATD08Antonio Di Nola and Revaz Grigolia • We recall that to any 1-variable McNaughton function fis associated apartition of the unit interval [0, 1] {0 = a0,a1, … , an = 1} in such a way that a0 < a1 < … < anand the points {(a0,f(a0)), (a1,f(a1)),… , (an,f(an))} are the knots of fand the function fis linear over each interval [ai-1,ai], with i = 1, … ,n. We assume that all considered functions are 1-variableMcNaughton functions. Notice that the MV -algebra of all 1-variable Mc-Naughton functions, as a set, is closed under functional composition.

On one-generated projective BL-algebras LATD08Antonio Di Nola and Revaz Grigolia f (a3) f (a1) f (a2) f (a4) = f (a0) a0 a1 a2 a3 a4

On one-generated projective BL-algebras LATD08Antonio Di Nola and Revaz Grigolia Theorem 2. Let A be a one-generated subalgebra of FMV(1) generated by f. Then the following are equivalent: (1) A is projective; (2) one of the following holds: (2.1) Max{f(x): x  [0,1]} = f(a1) and for f non-zero function, f(x) = x for everyx  [0,a1]. (2.2) Min{f(x): x  [0,1]} = f(an1) and for f non-unit function, f(x) = x for everyx  [an1,an].

On one-generated projective BL-algebras LATD08Antonio Di Nola and Revaz Grigolia

On one-generated projective BL-algebras LATD08Antonio Di Nola and Revaz Grigolia • On Z+ we define the function v1(x) as follows: • v1(1) = 2, • v1(2) =3 2 ,… , • v1(n) = (n+1) (v1(n1) +… + v1(nk-1)), where n1(= 1), … , nk-1are all the divisors of n distinct from n(= nk). Then,

On one-generated projective BL-algebras LATD08Antonio Di Nola and Revaz Grigolia Let Vn denotes the variety of BL-algebras generated by (n +1)-element BL-chains. Proposition 3.(A. Di Nola, R. Grigolia, Free BL-Algebras, Proceedings of the Institute of Cybernetics, ISSN 1512-1372, Georgian Academy of Sciences, Vol. 3,N 1-2(2004), pp. 22-31). A free cyclicBL-algebra FVn(1) S1S2v1(1) … Snv1(n)  (S1 ● (S1S2v1(1) … Snv1(n)))

On one-generated projective BL-algebras LATD08Antonio Di Nola and Revaz Grigolia Represent FVn(1) as a direct product AnAn+, where An = S1S2v1(1) … Snv1(n) and An+= S1 ● (S1S2v1(1) … Snv1(n)). Let g(n)and g(n)+ be generatorsof An and An+, respectively. The families {An}n{0} and {An+}n{0} formdirected set of algebras with homomorphisms hij: Aj Ai and hij+: Ai+Aj+ respectively. Let A be a inverse limit of the inverse system {An}n{0} and A+ a inverse limit of the inverse system {An+}n{0}.

On one-generated projective BL-algebras LATD08Antonio Di Nola and Revaz Grigolia • A subalgebra A of FK(m) is said to be projective if there exists an endomorphism h : FK(m) FK(m) such that h(FK(m)) = A and h(x) = x forevery x A.

On one-generated projective BL-algebras LATD08Antonio Di Nola and Revaz Grigolia Proposition 4.(A. Di Nola, R. Grigolia, Free BL-Algebras, Proceedings of the Institute of Cybernetics, ISSN 1512-1372, Georgian Academy of Sciences, Vol. 3,N 1-2(2004), pp. 22-31). The subalgebraFBL(1) ofAA+ generatedby (g,g+) =((g(1),g(2), …), (g(1)+; g(2)+, …)) is one-generated free BL-algebra.

On one-generated projective BL-algebras LATD08Antonio Di Nola and Revaz Grigolia Theorem 4.A proper subalgebra B of one-generated free BL-algebraFBL(1) generated by(a,b)is projectiveiffb = 1 or b= g+ and the subalgebra generated by (a,1) is a projective MV -algebra.

On one-generated projective BL-algebras LATD08Antonio Di Nola and Revaz Grigolia PROJECTIVE FORMULAS Let us denote by Pm a set of fixed p1, … ,pm propositional variables and bym all of Basic logic formulas with variables in Pm . Notice that them-generated free BL -algebra FBL(m) is isomorphic to m/ , where  iff | () and () =() (  )). Subsequently we do notdistinguish between the formulas and their equivalence classes. Hence wesimply write m for FBL(m), and Pm plays the role of free generators. Sincem is a lattice, we have an order on m . It follows from the denition of that for all  ,  m,   iff | .

On one-generated projective BL-algebras LATD08Antonio Di Nola and Revaz Grigolia Let  be a formula of Basic logic and consider asubstitution  :Pm m and extend it to all of m by ((p1, … , pm)) = ((p1), … , (pm)). We can consider the substitution as an endomorphism of the free algebram. Definition 5. A formula mis called projective if there exists asubstitution  : Pm m such that |() and | (),for allm.

On one-generated projective BL-algebras LATD08Antonio Di Nola and Revaz Grigolia Definition 6. An algebra A is called finitely presented if A is finitely generated, withthe generatorsa1, … , amA, and there exist a finite number of equations P1(x1, … , xm) = Q1(x1, … , xm) , … ,Pn(x1, … , xm) = Qn(x1, … , xm) holdingin A on the generatorsa1, … , amAsuch that if there exists an m-generated algebra B, with generators b1, … , bmB, such that the equations P1(x1, … , xm) = Q1(x1, … , xm) , … ,Pn(x1, … , xm) = Qn(x1, … , xm) holdin B on the generatorsb1, … , bmB, then there exists a homomorphismh : AB sending ai to bi.

On one-generated projective BL-algebras LATD08Antonio Di Nola and Revaz Grigolia Observe that we can rewrite any equation P(x1, … , xm) = Q(x1, … , xm) in the variety BL into an equivalent one P(x1, … , xm) Q(x1, … , xm) = 1. So, for BL we can replace n equations by one /\ni =1 Pi(x1, … , xm) Qi(x1, … , xm) = 1

On one-generated projective BL-algebras LATD08Antonio Di Nola and Revaz Grigolia Theorem 7. A BL-algebra B is finitely presentediffBm/[u), where[u) is a principal filter generated by some elementum.

On one-generated projective BL-algebras LATD08Antonio Di Nola and Revaz Grigolia Theorem 8.Let A be an m-generated projective BL-algebra. Then there exists a projective formula  of m variables, such that A is isomorphic to m/[), where [) is the principal filter generated by m.

On one-generated projective BL-algebras LATD08Antonio Di Nola and Revaz Grigolia Corollary 9.If A is a projective MV -algebra, then A is finitely presented. Theorem 10.If  is a projective formula of m variables, then m/[)is aprojective algebra.

On one-generated projective BL-algebras LATD08Antonio Di Nola and Revaz Grigolia Theorem11.There exists a one-to-one correspondence between projective formulas with m variables and m-genera-ted projective subalgebras of m.

Logic, Algebra and Truth Degrees 2008 September 8 to 11, Siena , Italy

Logic, Algebra and Truth Degrees 2008 September 8 to 11, Siena , Italy

Presentation Transcript

Truth Functional Logic

Boolean Algebra and Logic Simplification

September 11, 2008

Truth Tables and Boolean Algebra

Boolean Algebra and Logic Gates

Boolean Algebra and Logic Gates

Boolean Algebra and Digital Logic

8-11 September 2008 Chiang Mai, Thailand

Siena K – 8 School

Workshop - September 8, 2008

ITSS Roundup 11 September 2008

International Conference Logic, Algebra and Truth Degrees [LATD2008]

Logic Gates And Boolean Algebra

PTOL 2008-09 September 8, 2008

PAVI ’11 Rome, Italy September 2011

Logic: Truth Tables

8 September 2008

Logic Gates and Boolean Algebra

Boolean algebra and logic simplification

11 September 2008 Paris

Boolean algebra and logic gates

Boolean Algebra and Logic Simplification