Homomorphism and Cartesian Product on Fuzzy Translation and Fuzzy Multiplication of PS-algebras

Annals of Pure and Applied athematics Vol. 8, No. 1, 2014, 93-104 ISSN: 2279-087X (P), 2279-0888(online) Published on 11 November 2014 www.researchmathsci.org Annals of Homomorphism and Cartesian Product on Fuzzy ranslation and Fuzzy ultiplication of PS-algebras.Priya 1 and.ramachandran 2 1 Department of athematics, PSNA College of Engineering and echnology Dindigul 624 622, amilnadu, India E-mail : tpriyasuriya@gmail.com 2 Department of athematics,.v.uthiah Government Arts College for Women Dindigul 624 001, amilnadu, India E-mail : yasrams@yahoo.co.in Received 19 October 2014; accepted 8 November 2014 Abstract. In this paper, we define Homomorphism and Cartesian product on fuzzy translation and fuzzy muliplication of PS-algebras and discussed some of its properties in detail by using the concepts of fuzzy PS-ideal and fuzzy PS-sub algebra. Keywords: fuzzy-α-translation, fuzzy-α-multiplication of PS-algebra, fuzzy PS-ideal, fuzzy PS-sub algebra, homomorphism and Cartesian product. AS athematics Subject Classifications (2010): 06F35, 03G25 1. Introduction he concept of fuzzy set was initiated by Zadeh in 1965 [4]. It has opened up keen insights and applications in a wide range of scientific fields. Since its inception, the theory of fuzzy subsets has developed in many directions and found applications in a wide variety of fields. he study of fuzzy subsets and its applications to various mathematical contexts has given rise to what is now commonly called fuzzy mathematics. Fuzzy algebra is an important branch of fuzzy mathematics. Fuzzy ideas have been applied to other algebraic structures such as groups, rings, modules, vector spaces and topologies. In this way, Iseki and anaka [1] introduced the concept of BCKalgebras in 1978. Iseki [2] introduced the concept of BCI-algebras in 1980. It is known that the class of BCK-algebras is a proper subclass of the class of BCI-algebras. Priya and Ramachandran [6,7] introduced the class of PS-algebras, which is a generalization of BCI / BCK/Q / KU / d algebras and studied various properties [5,8,9]. In this paper, we introduce the concept homomorphism and Cartesian product of fuzzy-α-translation, fuzzy-α-multiplication of PS-algebras and established some of its properties in detail. 2. Preliminaries In this section, we introduced some fundamental definitions that will be used in the sequel. 93

.Priya and.ramachandran Definition 2.1. [1] A BCK- algebra is an algebra (X,*,0) of type(2,0) satisfying the following conditions: i) (x * y) * (x * z) (z * y) ii) x * (x * y) y iii) x x iv) x y and y x x=y v) 0 x x=0, where x y is defined by x * y = 0, for all x, y, z X. Definition 2.2. [2] A BCI-algebra is an algebra (X,*,0) of type(2,0) satisfying the following conditions: i) (x * y) *(x * z) (z*y) ii) x * (x * y) y iii) x x iv) x y and y x x = y v) x 0 x = 0, where x y is defined by x * y = 0,for all x, y, z X. Definition 2.3. [7] A nonempty set X with a constant 0 and a binary operation * is called PS algebra if it satisfies the following axioms. 1. x * x = 0 2. x * 0 = 0 3. x * y = 0 and y * x = 0 x = y, x, y X. Definition 2.4. [6] Let X be a PS-algebra. A fuzzy set µ in X is called a fuzzy PS-ideal of X if it satisfies the following conditions. i) µ(0) µ(x) ii) µ (x) min {µ (y *x), µ(y)}, for all x, y X. Definition 2.5. [6] A fuzzy set µ in a PS-algebra X is called a fuzzy PS- sub algebra of X if µ(x * y) min {µ(x), µ(y)}, for all x, y X. Remark. Let X be a PS-algebra. For any fuzzy set µ of X, we define = 1 sup{µ(x) / x X }, unless otherwise we specified. Definition 2.6. ([3,5,12]) Let µ be a fuzzy subset of X and α [0,]. A mapping µ α : X [0, 1] is said to be a fuzzy-α-translation of µ if it satisfies µ α (x) = µ(x) + α, x X. Definition 2.7. ([3,5,12]) Let µ be a fuzzy subset of X and α [ 0,1]. A mapping µ α : X [0, 1] is said to be a fuzzy-α-multiplication of µ if it satisfies µ α (x) = α µ(x), x X. Example 2.8. [5] Let X = { 0, 1, 2 } be the set with the following table. * 0 1 2 0 0 1 2 1 0 0 1 2 0 2 0 94

Homomorphism and Cartesian Product on Fuzzy ranslation and Fuzzy ultiplication of PS-algebras hen (X, *, 0 ) is a PS algebra. 0.3 if x 1 Define a fuzzy set µ of X by µ(x) =. 0.2 if x = 1 hen µ is a fuzzy PS-sub algebra of X. Here = 1 sup {µ(x) / x X} = 1 0.3 = 0.7, Choose α= 0.4 [0, ] and β = 0.5 [0, 1]. 0.3+ 0.4 = 0.7 if x 1 hen the mapping µ 0.4 : X [0, 1] is defined by µ 0.4 = 0.2 + 0.4 = 0.6 if x = 1 which satisfies µ 0.4 (x) = µ(x) + 0.4, x X, is a fuzzy 0.4-translation and the mapping (0.5)(0.3) = 0.15 if x 1 µ 0.5 : X [0, 1] is defined by µ 0.5 (x) = (0.5)(0.2) = 0.10 if x = 1 which satisfies µ 0.5 (x) = (0.5)µ(x), x X, is a fuzzy 0.5-multiplication. 3. Homomorphism on fuzzy translation and fuzzy multiplication In this section, we discuss homomorphism on fuzzy translation and fuzzy multiplication of PS-algebra and proved certain results on the basis of fuzzy PS-ideal and fuzzy PS- sub algebra. Definition 3.1. [10][13] Let f: X X be an endomorphism and µ α be a fuzzy -αtranslation of µ in X. We define a new fuzzy set in X by (µ α ) f in X as ( µ α ) f (x) = ( µ α ) (f(x)) = µ[f(x)] + α, x X. heorem 3.2. Let f be an endomorphism of PS- algebra X. If µ is a fuzzy PS-ideal of X, then so is ( µ α ) f. Proof: Let µ be a fuzzy PS-ideal of X. Now, (µ α ) f (0) = µ α [ f(0)] = µ [ f(0) ] + α µ [ f(x) ] + α = ( µ α ) (f(x)) = (µ α ) f (x) (µ α ) f (0) (µ α ) f (x) Let x,y X. hen (µ α ) f (x) = µ α [f( x)] = µ [ f(x) ] + α min { µ (f(y) * f(x)), µ(f (y))} + α = min { µ ( f( y * x ) ), µ(f (y))} + α = min { µ ( f( y * x ) ) + α, µ(f (y)) + α} = min { µ α [f( y * x )], µ α [f(y)]} = min { (µ α ) f ( y * x ), (µ α ) f (y) } (µ α ) f ( x ) min { (µ α ) f ( y * x ), (µ α ) f (y) } Hence (µ α ) f is a fuzzy PS-ideal of X. 95

.Priya and.ramachandran heorem 3.3. Let f: X Y be an epimorphism of PS- algebra. If (µ α ) f is a fuzzy PSideal of X, then µ is a fuzzy PS-ideal of Y. Proof: Let (µ α ) f be a fuzzy PS-ideal of X and let y Y. hen there exists x X such that f(x) = y. Now, µ(0) + α = µ α (0) = µ α [f(0)] = (µ α ) f (0) (µ α ) f (x) = µ α [f(x)] = µ[f(x)] + α and so µ(0) µ[f(x)] = µ (y). µ (0) µ (y ) Let y 1, y 2 Y. µ( y 1 ) + α = µ α (y 1 ) = µ α (f (x 1 )) = (µ α ) f ( x 1 ) min { (µ α ) f ( x 2 * x 1 ), (µ α ) f ( x 2 ) } = min { µ α [f (x 2 * x 1 )], µ α [f(x 2 )] } = min { µ α [f (x 2 ) * f(x 1 )], µ α [f( x 2 )] } = min { µ α [ y 2 * y 1 ], µ α [y 2 ] } = min { µ (y 2 * y 1 ) + α, µ(y 2 ) + α } = min {µ (y 2 * y 1 ), µ(y 2 )} + α µ (y 1 ) min { µ ( y 2 * y 1 ), µ(y 2 )} µ is a fuzzy PS-ideal of Y. heorem 3.4. Let f: X Y be a homomorphism of PS- algebra. If µ is a fuzzy PS-ideal of Y then (µ α ) f is a fuzzy PS-ideal of X. Proof: Let µ be a fuzzy PS-ideal of Y and let x,y X. hen (µ α ) f (0) = µ α [f(0)] = µ (f(0)) + α µ (f(x)) + α = µ α [ f(x)] = (µ α ) f (x) (µ α ) f (0) (µ α ) f (x). Also (µ α ) f (x) = µ α [ f (x ) ] = µ (f(x)) + α min { µ ( f(y) * f(x) ), µ ( f (y) ) } + α = min { µ ( f( y * x) ), µ ( f (y) ) } + α = min { µ ( f( y * x) ) + α, µ ( f (y) ) + α } = min { µ α [ f( y * x) ], µ α [ f (y) ]} = min { (µ α ) f (y * x), (µ α ) f (y) } (µ α ) f ( x ) min { (µ α ) f (y * x), (µ α ) f (y) }. Hence (µ α ) f is a fuzzy PS-ideal of X. heorem 3.5. If µ is a fuzzy PS- sub algebra of X, then (µ α ) f is also a fuzzy PS-sub algebra of X. 96

Homomorphism and Cartesian Product on Fuzzy ranslation and Fuzzy ultiplication of PS-algebras Proof: Let µ be a fuzzy PS- sub algebra of X. Let x, y X. Now, (µ α ) f (x* y) = µ α [ f (x *y) ] = µ [ f (x *y) ] + α = µ ( f (x) * f(y) ) + α min {µ (f (x)), µ(f(y)) } + α = min {µ (f (x)) + α, µ (f(y)) + α } = min {µ α [f (x)], µ α [f(y)] } = min {(µ α ) f (x), (µ α ) f (y) } (µ α ) f (x* y) min {(µ α ) f (x), (µ α ) f (y) } Hence (µ α ) f is a fuzzy PS-sub algebra of X. heorem 3.6. Let f: X Y be a homomorphism of a PS-algebra X into a PS-algebra Y and µ α be a fuzzy - α - translation of µ, then the pre- image of µ α denoted by f -1 (µ α ) is defined as {f -1 (µ α )}(x) = µ α (f(x)), x X. If µ is a fuzzy PS- sub algebra of Y, then f -1 (µ α ) is a fuzzy PS- sub algebra of X. Proof: Let µ be a fuzzy PS- sub algebra of Y. Let x, y X. Now, {f -1 (µ α )}(x* y) = µ α [ f (x *y) ] = µ [ f (x *y) ] + α = µ [ f (x) * f(y) ] + α min { µ [f (x)], µ [f(y)] } + α = min { µ [f (x)] + α, µ [f(y)] + α } = min { µ α [f (x)], µ α [f(y)] } = min {{f -1 (µ α )} (x), {f -1 (µ α )}(y) } f -1 (µ α )}(x* y) min {{f -1 (µ α )} (x), {f -1 (µ α )}(y) } f -1 (µ α ) is a fuzzy PS-sub algebra of X. Definition 3.7. Let f: X X be an endomorphism and µ α be a fuzzy-α-multiplication of µ in X. We define a new fuzzy set in X by (µ α ) f in X as ( µ α ) f (x) = ( µ α ) [f(x)] = α µ[f(x)], x X. heorem 3.8. Let f be an endomorphism of PS- algebra X. If µ is a fuzzy PS-ideal of X, then so is ( µ α ) f. Proof: Let µ be a fuzzy PS-ideal of X. Now, (µ α ) f (0) = µ α [ f(0)] = α µ [ f(0) ] α µ [ f(x) ] = ( µ α ) (f(x)) = (µ α ) f (x) (µ α ) f (0) (µ α ) f (x) Let x,y X. hen (µ α ) f (x) = µ α [f( x)] = α µ [ f(x) ] α min { µ (f(y) * f(x)), µ(f (y))} = α min { µ ( f( y * x ) ), µ(f (y))} 97

.Priya and.ramachandran = min {α µ ( f( y * x ) ), α µ(f (y)) } = min { µ α [f( y * x )], µ α [f(y)]} = min { (µ α ) f ( y * x ), (µ α ) f (y) } (µ α ) f ( x ) min { (µ α ) f ( y * x ), (µ α ) f (y) } Hence (µ α ) f is a fuzzy PS-ideal of X. heorem 3.9. Let f: X Y be an epimorphism of PS- algebra. If (µ α ) f is a fuzzy PSideal of X, then µ is a fuzzy PS-ideal of Y. Proof: Let (µ α ) f be a fuzzy PS-ideal of X and let y Y. hen there exists x X such that f(x) = y. Now, α µ(0) = µ α (0) = µ α [ f(0)] = (µ α ) f (0) (µ α ) f (x) = µ α [f(x)] = α µ[f(x)] µ(0) µ[f(x)] = µ (y). µ (0) µ (y ) Let y 1, y 2 Y. α µ(y 1 ) = µ α [y 1 ] = µ α [f (x 1 )] = (µ α ) f ( x 1 ) min { (µ α ) f ( x 2 * x 1 ), (µ α ) f ( x 2 ) } = min { µ α [f (x 2 * x 1 )], µ α [f(x 2 )] } = min { µ α [f (x 2 ) * f(x 1 )], µ α [f( x 2 )] } = min { µ α [ y 2 * y 1 ], µ α [y 2 ] } = min { α µ (y 2 * y 1 ), α µ(y 2 ) } = α min {µ (y 2 * y 1 ), µ(y 2 )} µ (y 1 ) min { µ ( y 2 * y 1 ), µ(y 2 )} µ is a fuzzy PS-ideal of Y. heorem 3.10. Let f: X Y be a homomorphism of PS- algebra. If µ is a fuzzy PS-ideal of Y then (µ α ) f is a fuzzy PS-ideal of X. Proof: Let µ be a fuzzy PS-ideal of Y and let x,y X. hen (µ α ) f (0) = µ α [f(0)] = α µ (f(0)) α µ (f(x)) = µ α [ f(x)] = (µ α ) f (x) (µ α ) f (0) (µ α ) f (x). Also, (µ α ) f (x) = µ α [ f (x ) ] = α µ (f(x)) α min { µ ( f(y) * f(x) ), µ ( f (y) ) } = α min { µ ( f( y * x) ), µ ( f (y) ) } = min { α µ ( f( y * x) ), α µ ( f (y) ) } 98

Homomorphism and Cartesian Product on Fuzzy ranslation and Fuzzy ultiplication of PS-algebras = min { µ α [ f( y * x) ], µ α [ f (y) ]} = min { (µ α ) f (y * x), (µ α ) f (y) } (µ α ) f ( x ) min { (µ α ) f (y * x), (µ α ) f (y) }. Hence (µ α ) f is a fuzzy PS-ideal of X. heorem 3.11. If µ be a fuzzy PS- sub algebra of X, then (µ α ) f is also a fuzzy PS-sub algebra of X. Proof: Let µ be a fuzzy PS- sub algebra of X. Let x, y X. Now, (µ α ) f (x* y) = µ α [ f (x *y)] = α µ [ f (x *y)] = α µ ( f (x) * f(y)) α min{µ (f (x)),µ(f(y))} = min{α µ (f (x)),α µ (f(y))} = min{µ α [f (x)], µ α [f(y)]} = min {(µ α ) f (x), (µ α ) f (y)} (µ α ) f is a fuzzy PS-sub algebra of X. heorem 3.12. Let f: X Y be a homomorphism of a PS-algebra X into a PS-algebra Y and µ α be a fuzzy - α - multiplication of µ, then the pre- image of µ α denoted by f -1 (µ α ) is defined as {f -1 (µ α )}(x) = µ α (f(x)), x X. If µ is a fuzzy PS- sub algebra of Y, then f -1 (µ α ) is a fuzzy PS- sub algebra of X. Proof: Let µ be a fuzzy PS- sub algebra of Y. Let x, y X. Now, {f -1 (µ α )}(x* y) = µ α [ f (x *y) ] = α µ [ f (x *y) ] = α µ [ f (x) * f(y) ] α min { µ [f (x)], µ [f(y)] } = min {α µ [f (x)], α µ [f(y)] } = min { µ α [f (x)], µ α [f(y)] } = min {{f -1 (µ α )} (x), {f -1 (µ α )}(y) } f -1 (µ α )}(x* y) min {{f -1 (µ α )} (x), {f -1 (µ α )}(y) } f -1 (µ α ) is a fuzzy PS-sub algebra of X. 4. Cartesian product on fuzzy translation and fuzzy multiplication In this section, we discuss the Cartesian product of fuzzy translation and fuzzy multiplication of PS-algebras and establish some of its properties in detail on the basis of fuzzy PS-ideal and fuzzy PS- sub algebra. Definition 4.1. ([11,14]) Let µ α and δ α be the fuzzy sets in X. hen Cartesian product µ α xδ α :X x X [0,1] is defined by ( µ α x δ α ) ( x, y) = min {µ α (x), δ α (y)}, for all x, y X. heorem 4.2. If µ and δ are fuzzy PS-idels in a PS algebra X, then µ α x δ α is a fuzzy PS-ideal in X x X. 99

.Priya and.ramachandran Proof: Let ( x 1, x 2 ) X x X. ( µ α x δ α ) (0,0) = min { µ α (0), δ α (0) } = min { µ (0) + α, δ (0) + α } = min { µ (0), δ (0) } + α min { µ (x 1 ), δ (x 2 ) } + α = min { µ (x 1 ) + α, δ (x 2 ) + α } = min { µ α (x 1 ), δ α (x 2 ) } = (µ α x δ α ) (x 1, x 2 ) Let ( x 1, x 2 ), ( y 1, y 2 ) X x X. (µ α x δ α ) ( x 1, x 2 ) = min { µ α ( x 1 ), δ α ( x 2 ) } = min { µ (x 1 ) + α, δ (x 2 ) + α } = min { µ (x 1 ), δ (x 2 ) } + α min { min {µ (y 1 * x 1 ), µ (y 1 )}, min {δ (y 2 * x 2 ), δ (y 2 )}} + α = min {min {µ (y 1 * x 1 ), µ (y 1 )} + α, min {δ (y 2 * x 2 ), δ (y 2 )} + α} = min{min {µ (y 1 * x 1 ) +α, µ (y 1 ) +α}, min {δ (y 2 * x 2 ) +α, δ (y 2 ) +α}} = min {min {µ α (y 1 * x 1 ), µ α (y 1 )}, min {δ α (y 2 * x 2 ), δ α (y 2 )}} = min {min {µ α (y 1 * x 1 ), δ α (y 2 * x 2 )}, min {µ α (y 1 ), δ α (y 2 )} = min {(µ α x δ α ) ( ( y 1 * x 1 ),( y 2 * x 2 ), (µ α x δ α ) (y 1, y 2 )} = min {(µ α x δ α ) ( (y 1, y 2 ) * (x 1, x 2 ) ), (µ α x δ α ) (y 1, y 2 )} (µ α x δ α ) (x 1, x 2 ) min {(µ α x δ α ) ( (y 1, y 2 ) * (x 1, x 2 ) ), (µ α x δ α ) (y 1, y 2 )}. Hence µ α x δ α is a fuzzy PS- ideal in X x X. heorem 4.3. Let µ & δ be fuzzy sets in a PS-algebra X such that µ α x δ α is a fuzzy PS-ideal of X x X. hen (i) Either µ α (0) µ α (x) (or) δ α (0) δ α (x) for all x X. (ii) If µ α (0) µ α (x) for all x X, then either δ α (0) µ α (x) (or) δ α (0) δ α (x) (iii) If δ α (0) δ α (x) for all x X, then either µ α (0) µ α (x) (or) µ α (0) δ α (x) Proof: Let µ α x δ α be a fuzzy PS-ideal of X x X. (i) Suppose that µ α (0) < µ α (x) and δ α (0) < δ α (x) for some x, y X. hen (µ α x δ α ) (x,y) = min{ µ α (x), δ α (y) } > min { µ α (0), δ α (0) } = (µ α x δ α ) (0, 0), which is a contradiction. herefore µ α (0) µ α (x) (or) δ α (0) δ α (x) for all x X. (ii) Assume that there exists x, y X such that δ α (0) < µ α (x) and δ α (0) < δ α (x). hen (µ α x δ α ) (0,0) = min { µ α (0), δ α (0) } = δ α (0) and hence (µ α x δ α ) (x, y) = min {µ α (x),δ α (y)} > δ α (0) = (µ α x δ α ) (0,0) Which is a contradiction. Hence, if µ α (0) µ α (x) for all x X, then either δ α (0) µ α (x) (or) δ α (0) δ α (x). Similarly, we can prove that if δ α (0) δ α (x) for all x X, then either µ α (0) µ α (x) (or) µ α (0) δ α (x), which yields (iii). heorem 4.4. Let µ & δ be fuzzy sets in a PS-algebra X such that µ α x δ α is a fuzzy PS-ideal of X x X. hen either µ or δ is a fuzzy PS-ideal of X. Proof: First we prove that δ is a fuzzy PS-ideal of X. 100

Homomorphism and Cartesian Product on Fuzzy ranslation and Fuzzy ultiplication of PS-algebras Since by 4.5.3 (i) either µ α (0) µ α (x) (or) δ α (0) δ α (x) for all x X. Assume that δ α (0) δ α (x) for all x X. δ(0) + α δ(x) + α. δ (0) δ (x). It follows from 4.5.3 (iii) that either µ α (0) µ α (x) (or) µ α (0) δ α (x). If µ α (0) δ α (x), for any x X, then δ α (x) = min {µ α (0), δ α (x)} = (µ α x δ α ) (0, x) δ(x) + α = δ α (x) = (µ α x δ α ) (0, x) min {(µ α x δ α ) ( (0,y) * (0,x) ), (µ α x δ α ) (0, y)} = min {(µ α x δ α ) ( (0*0),(y*x) ), (µ α x δ α ) (0, y)} = min {(µ α x δ α ) (0,(y*x) ), (µ α x δ α ) (0, y)} = min { δ α (y*x), δ α (y)} = min { δ (y * x) + α, δ (y) + α} = min { δ (y * x), δ (y) } + α δ(x) min { δ (y * x), δ (y) } Hence δ is a fuzzy PS-ideal of X. Next we will prove that µ is a fuzzy PS-ideal of X. Let µ α (0) µ α (x). µ (0) µ (x) Since by theorem 4.5.3 (ii), either δ α (0) µ α (x) (or) δ α (0) δ α (x). Assume that δ α (0) µ α (x), then µ α (x) = min { µ α (x), δ α (0)} = (µ α x δ α ) (x,0). µ(x) + α = µ α (x) = (µ α x δ α ) (x,0) min{(µ α x δ α )( (y,0) * (x,0) ), (µ α x δ α ) (y,0)} = min {(µ α x δ α ) ( (y * x), (0*0) ), (µ α x δ α ) (y,0)} = min {(µ α x δ α ) ( (y * x), 0 ), (µ α x δ α ) (y,0)} = min {µ α (y * x), µ α (y)} = min { µ (y * x ) + α, µ (y) + α } = min { µ (y * x ), µ (y) } + α µ(x) min { µ (y * x ), µ (y) } Hence µ is a fuzzy PS-ideal of X. heorem 4.5. If µ and δ are fuzzy PS-sub algebras of a PS-algebra X, then µ α x δ α is also a fuzzy PS-sub algebra of X x X. Proof: For any x 1, x 2, y 1, y 2 X. (µ α x δ α ) ( (x 1, y 1 ) * ( x 2, y 2 ) ) = (µ α x δ α ) ( x 1 * x 2, y 1 * y 2 ) = min { µ α ( x 1 * x 2 ), δ α ( y 1 * y 2 ) } = min { µ ( x 1 * x 2 ) + α, δ ( y 1 * y 2 ) + α } = min { µ ( x 1 * x 2 ), δ ( y 1 * y 2 ) } + α min { min {µ (x 1 ), µ (x 2 )},min{δ( y 1 ), δ( y 2 )}} + α = min { min {µ (x 1 ), µ (x 2 )} +α,min{δ( y 1 ),δ( y 2 )}+ α } = min {min{µ (x 1 ) +α, µ (x 2 ) +α},min{δ( y 1 )+α,δ(y 2 ) + α}} = min {min { µ α (x 1 ), µ α (x 2 ) }, min { δ α (y 1 ), δ α (y 2 )} = min { min {µ α (x 1 ),δ α (y 1 )}, min {µ α (x 2 ), δ α (y 2 )} } = min { (µ α x δ α ) ( x 1, y 1 ), (µ α x δ α ) ( x 2, y 2 ) } 101

.Priya and.ramachandran (µ α x δ α ) ( (x 1, y 1 ) * ( x 2, y 2 ) ) min { (µ α x δ α ) ( x 1, y 1 ), (µ α x δ α ) ( x 2, y 2 ) } his completes the proof. heorem 4.6. If µ and δ are fuzzy PS-ideals in a PS-algebra X, then µ α x δ α is a fuzzy PS-ideal in X x X. Proof: Let ( x 1, x 2 ) X x X. ( µ α x δ α ) (0,0) = min { µ α (0), δ α (0) } = min { α µ (0), α δ (0) } = α min { µ (0), δ (0) } α min { µ (x 1 ), δ (x 2 ) } = min { α µ (x 1 ), α δ (x 2 ) } = min { µ α (x 1 ), δ α (x 2 ) } = (µ α x δ α ) (x 1, x 2 ) Let ( x 1, x 2 ), ( y 1, y 2 ) X x X. (µ α x δ α ) ( x 1, x 2 ) = min { µ α ( x 1 ), δ α ( x 2 ) } = min { α µ (x 1 ), α δ (x 2 ) } = α min { µ (x 1 ), δ (x 2 ) } α min { min {µ (y 1 * x 1 ), µ (y 1 )}, min {δ (y 2 * x 2 ), δ (y 2 )}} = min {α min {µ (y 1 * x 1 ), µ (y 1 )}, α min {δ (y 2 * x 2 ), δ (y 2 )} } = min {min {α µ (y 1 * x 1 ), α µ (y 1 )}, min {α δ (y 2 * x 2 ),α δ (y 2 ) } = min {min {µ α (y 1 * x 1 ), µ α (y 1 )}, min {δ α (y 2 * x 2 ), δ α (y 2 )} = min {min {µ α (y 1 * x 1 ), δ α (y 2 * x 2 )}, min {µ α (y 1 ), δ α (y 2 )} = min {(µ α x δ α ) ( ( y 1 * x 1 ),( y 2 * x 2 ), (µ α x δ α ) (y 1, y 2 ) } = min {(µ α x δ α ) ( (y 1, y 2 ) * (x 1, x 2 ) ), (µ α x δ α ) (y 1, y 2 )} (µ α x δ α ) (x 1, x 2 ) min {(µ α x δ α ) ( (y 1, y 2 ) * (x 1, x 2 ) ), (µ α x δ α ) (y 1, y 2 )}. Hence µ α x δ α is a fuzzy PS- ideal in X x X. heorem 4.7. Let µ & δ be fuzzy sets in a PS-algebra X such that µ α x δ α is a fuzzy PS-ideal of X x X. hen (i) Either µ α (0) µ α (x) (or) δ α (0) δ α (x) for all x X. (ii) If µ α (0) µ α (x) for all x X, then either δ α (0) µ α (x) (or) δ α (0) δ α (x) (iii) If δ α (0) δ α (x) for all x X, then either µ α (0) µ α (x) (or) µ α (0) δ α (x) Proof: Straight forward. heorem 4.8. Let µ & δ be fuzzy sets in a PS-algebra X such that µ α x δ α is a fuzzy PS-ideal of X x X. hen either µ or δ is a fuzzy PS-ideal of X. Proof: First we prove that δ is a fuzzy PS-ideal of X. Since by 4.5.3 (i) either µ α (0) µ α (x) (or) δ α (0) δ α (x) for all x X. Assume that δ α (0) δ α (x) for all x X. α δ(0) α δ(x). δ (0) δ (x) It follows from 4.5.3 (iii) that either µ α (0) µ α (x) (or) µ α (0) δ α (x). If µ α (0) δ α (x), for any x X, then δ α (x) = min {µ α (0), δ α (x)} = (µ α x δ α ) (0, x) α δ(x) = δ α (x) = (µ α x δ α ) (0, x) 102

Homomorphism and Cartesian Product on Fuzzy ranslation and Fuzzy ultiplication of PS-algebras min {(µ α x δ α ) ( (0,y) * (0,x) ), (µ α x δ α ) (0, y)} = min {(µ α x δ α ) ( (0*0),(y*x) ), (µ α x δ α ) (0, y)} = min {(µ α x δ α ) (0,(y*x) ), (µ α x δ α ) (0, y)} = min { δ α (y*x), δ α (y)} = min { α δ (y * x), α δ (y) } = α min { δ (y * x), δ (y) } δ(x) min { δ (y * x), δ (y) } Hence δ is a fuzzy PS-ideal of X. Similarly we will prove that µ is a fuzzy PS-ideal of X. heorem 4.9. If µ and δ are fuzzy PS-sub algebras of a PS-algebra X, then µ α x δ α is also a fuzzy PS-sub algebra of X x X. Proof: For any x 1, x 2, y 1, y 2 X. (µ α x δ α ) ( (x 1, y 1 ) * ( x 2, y 2 ) ) = (µ α x δ α ) ( x 1 * x 2, y 1 * y 2 ) = min { µ α ( x 1 * x 2 ), δ α ( y 1 * y 2 ) } = min { α µ ( x 1 * x 2 ), α δ ( y 1 * y 2 ) } = α min { µ ( x 1 * x 2 ), δ ( y 1 * y 2 ) } α min { min {µ (x 1 ), µ (x 2 )},min{δ( y 1 ), δ( y 2 )}} = min { α min {µ (x 1 ), µ (x 2 )}, α min{δ( y 1 ),δ( y 2 )} } = min{min{α µ(x 1 ), α µ (x 2 )}, min{ α δ( y 1 ), α δ(y 2 )}} = min{min{µ α (x 1 ), µ α (x 2 )},min {δ α (y 1 ), δ α (y 2 )} = min{min{µ α (x 1 ),δ α (y 1 )},min {µ α (x 2 ),δ α (y 2 )}} = min { (µ α x δ α ) ( x 1, y 1 ), (µ α x δ α ) ( x 2, y 2 ) } (µ α x δ α ) ( (x 1, y 1 ) * ( x 2, y 2 ) ) min { (µ α x δ α ) ( x 1, y 1 ), (µ α x δ α ) ( x 2, y 2 ) } his completes the proof. 5. Conclusion In this article we have been discussed homomorphism and Cartesian product on fuzzy translation and fuzzy muliplication of PS-algebras. It adds an another dimension to the defined PS--algebras. his concept can further be generalized to intuitionistic fuzzy set, interval valued fuzzy sets for new results in our future work. 6.Acknowledgement Authors wish to thank Dr. K..Nagalakshmi, Professor and Head, Department of athematics, K L N College of Information and echnology, Pottapalayam, Sivagangai District, amilnadu, India, Prof. P..Sithar Selvam, Professor and Head, Department of athematics, RVS School of Engineering and echnology, Dindigul, amilnadu, India, for their help to make this paper as successful one. Also we wish to thank Prof. adhumangal Pal, Editor in-chief and reviewers for their suggestions to improve this paper in excellent manner. REFERENCES 1. K.Iseki and S.anaka, An introduction to the theory of BCK algebras, ath. Japonica, 23 (1978) 1-20. 103

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