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INT-SOFT MIGHTY FILTERS IN BE-ALGEBRAS

  • KIM, YOUNG HEE (Department of Mathematics, College of Natural Science, Chungbuk National University) ;
  • PARK, (Department of Mathematics, College of Natural Science, Chungbuk National University)
  • Received : 2016.03.30
  • Accepted : 2016.06.12
  • Published : 2016.09.30

Abstract

In this paper, we introduce the notions about int-soft mighty filters, int-soft n-fold mighty filters, and int-soft n-fold positive implicative filters of BE-algebras. We investigate their properties and provide conditions which have connecting relationship among int-soft filters, int-soft mighty filters, and int-soft positive implicative filters. Also, characterizations of int-soft n-fold mighty filters and int-soft n-fold positive implicative filters are provided in BE-algebras.

Keywords

1. Introduction

Two classes of abstract algebras called BCK-algebra and BCI-algebra were introduced by K. Iséki and S. Tanaka ([5,6,7] The class of BCK-algebra is a proper subclass of the class of BCI-algebras. The BCK and BCI-algebras were more investigated as a generalization of propositional logics ([13,14]). Especially, H. S. Kim and Y. H. Kim established the concepts and properties of BE-algebras as a dualization for a generalization of BCK-algebras ([9]).

Sometimes it is not able to apply with classical methods successfully for many of complicated problems in engineering, economics, medical science, and environment because of various uncertainties. We investigate to approach their vagueness with wide extended ranges for theories of probability, fuzzy sets, vague sets, and other mathematical tools. However, most of these theories still have their own difficulties because of inadequate parametrization tools of the theories. To overcome these difficulties, the concept of soft set as a mathematical tool was suggested by D. Molodtsov ([15]). Since then the soft set which is a parameterized family of subsets of a universe has been based on algebraic structures by several authors. Acar et al.([1]) introduced initial concepts of soft rings and the notion of an int-soft filter in a BE-algebra was discussed by Ahn et al.([2]).

In this paper, we review some definitions and properties for positive implicative filters, mighty filters, and int-soft filters in BE-algebras. We define the notions for an int-soft mighty filter, an int-soft n-fold mighty filter, and an int-soft n-fold positive implicative filter of BE-algebras. We investigate their properties and provide several examples to clarify them. We introduce a condition for a mighty filter to be a positive implicative filter and then state some properties between int-soft mighty filters and int-soft positive implicative filters in a BE-algebra. We discuss characterizations of int-soft n-fold mighty filters and int-soft n-fold positive implicative filters of BE-algebras.

 

2. Preliminaries

We recall some definitions and results that will be useful in the process of our paper.

Definition 2.1 ([9]). An algebra (X; ∗, 1) is called a BE-algebra if it satisfies:

We introduce a relation “≤” on X by x ≤ y if and only if x ∗ y = 1: A BE-algebra (X; ∗, 1) is said to be self-distributive if x ∗ (y ∗ z) = (x ∗ y) ∗ (x ∗ z), commutative if (x∗y)∗y = y∗(y∗x) ([16]), and transitive if y∗z ≤ (x∗y)∗(x∗z). for all x, y, z ∈ X ([4]).

Definition 2.2 ([9]). Let (X; ∗, 1) be a BE-algebra and F a non-empty subset of X. Then F is called a filter of X if it satisfies:

Proposition 2.3 ([9]). Let (X; ∗, 1) be a self-distributive BE-algebra, then the followings hold: for any x, y, z ∈ X,

A BE-algebra (X; ∗, 1) is commutative, X has the same properties of Proposition 2.3 ([3,16]).

Proposition 2.4 ([4]). Let (X; ∗, 1) be a BE-algebra and F a filter of X. If x ≤ y and x ∈ F, then y ∈ F for any x, y ∈ X.

Definition 2.5 ([10]). Let X be a BE-algebra. A nonempty subset F of X is called a positive implicative filter of X if it satisfies:

Every positive implicative filter of a BE algebra X is a filter of X.

Theorem 2.6 ([10]). Let F be a filter of a BE-algebra X. Then F is a positive implicative filter of X if and only if

Definition 2.7 ([12]). A non-empty subset F of a BE-algebra X is called a mighty filter of X if it satisfies:

Every mighty filter of a BE-algebra X is a filter of X.

Theorem 2.8 ([12]). A filter F of a BE-algebra X is a mighty filter of X if and only if it satisfies :

In what follows, we take a BE-algebra X as a set of parameters unless otherwise specified. Let U be an initial universe set, A,B,C · ·· ⊆ X and P(U) denote the power set of U.

A soft set (f,A) of X over U ([15]) is defined to be the set of ordered pairs (f,A) := {{(x, f(x) : x ∈ X, f(x) ∈ P(U)}; where f : X → P(U) such that if x ∉ A.

Definition 2.9 ([2]). A soft set (f,X) of a BE-algebra X over U is called an intersection-soft filter (briefly, int-soft filter) over U if it satisfies: for any x, y ∈ X,

Proposition 2.10 ([2]). Every int-soft filter (f,X) of a BE-algebra X over U satisfies the following properties:

Proposition 2.11. Every int-soft filter (f,X) of a BE-algebra X over U satisfies the followings:

Proof. In BE-algebra, it satisfies x ≤ (x∗y)∗y. Thus it is implied f(x) ⊆ f((x∗y) ∗ y) by Proposition 2.10-(1). It has the same way in the cases of (2), (3). □

Proposition 2.12 ([8]). Let (f,X) be a soft set of a BE-algebra X over U, then (f,X) is an int-soft filter of X over U if and only if

 

3. Int-soft mighty filters in BE-algebras

In this section, we define an int-soft mighty filter of a BE-algebra. We investigate some relations among int-soft filter, int-soft mighty filter, and int-soft positive implicative filter in BE-algebras.

Definition 3.1. A soft (f,X) of a BE-algebra X over U is called an int-soft mighty filter of X over U if it satisfies:

Theorem 3.2. Every int-soft mighty filter of a BE-algebra X is an int-soft filter of X.

Proof. Let (f,X) be an int-soft mighty filter of X. If we take y = 1 in (IM2), f(x∗(1∗z))∩f(x) ⊆ f(((z ∗1)∗1)∗z) ⇒ f(x∗z)∩f(x) ⊆ f(z) for any x, z ∈ X. Thus (f,X) is an int-soft filter of X.

Example 3.3. Let X be a set of parameters and U = X the initial universe set. Let X := {1, a, b, c, d} be a BE-algebra with the following Cayley table:

Let a soft set (f,X) be a soft set of X over U defined as follows:

where γ1 and γ2 are subsets of U with . It is easy to check that (f,X) is both an int-soft mighty filter of X and an int-soft filter of X over U.

The converse of Theorem 3.2 is not true in general as the following example.

Example 3.4. Let X := {1, a, b, c, d}, then X is a BE-algebra with the following Cayley table:

Let a soft set (f,X) be defined as follows:

where γ1 and γ2 are subsets of U with . Then (f,X) is an int-soft filter, but (f,X) is not an int-soft mighty filter since f(1 ∗ (c ∗ b)) ∩ f(1) = = f(((b ∗ c) ∗ c) ∗ b).

Theorem 3.5. An int-soft filter is an int-soft mighty filter of a BE-algebra X if and only if

Proof. Assume X is an int-soft mighty filter and y, z ∈ X.

Conversely, let X is an int-soft filter and x, y, z ∈ X.

Thus it is an int-soft mighty filter of X. □

Theorem 3.6. Let (f,X) and (g,X) be int-soft filters of a transitive BE-algebra X with f(x) ⊆ g(x) and f(1) = g(1). If (f,X) is an int-soft mighty filter of X, then so is (g,X).

Proof. Suppose (f,X) is an int-soft mighty filter of a be-algebra X. Let x, y ∈ X, using Theorem 3.5, we have f(1) = f(y∗((y∗x)∗x)) ⊆ f(((((y∗x)∗x)∗y)∗y)∗((y∗x)∗x)) ⊆ g(((((y∗x)∗x)∗y)∗y)∗((y∗x)∗x)) = g((y∗x)∗(((((y∗x)∗x)∗y)∗y)∗x)) = g(1) since f(1) = g(1). It follows from Definition 2.9 that

Since X is transitive,

We get g(((((y ∗ x) ∗ x) ∗ y) ∗ y) ∗ x) ∩ g(1) ⊆ g(((x ∗ y) ∗ y) ∗ x) by Proposition 2.12. Thus g(y ∗x) ⊆ g(((((y ∗x) ∗x) ∗ y) ∗ y) ∗x) ⊆ g(((x∗ y) ∗ y) ∗x). It satisfies Theorem 3.5. Thus (g,X) is an int-soft mighty filter of X. □

We introduce a condition for a mighty filter to be a positive implicative filter and then provide some properties of int-soft mighty filters and int-soft positive implicative filters in a BE-algebra.

Theorem 3.7. Every positive implicative filter of a commutative BE-algebraX is a mighty filter of X.

Proof. Suppose a subset F of a BE-algebra X is a positive implicative filter. Using the commutative property of Proposition 2.3-(3), let y∗x ∈ F for x, y ∈ X.

We get ((((x ∗ y) ∗ y) ∗ x) ∗ x) ∗ (((x ∗ y) ∗ y) ∗ x) ∈ F by Proposition 2.4, so that ((x ∗ y) ∗ y) ∗ x ∈ F by Theorem 2.6. Hence F satisfies Theorem 2.8. □

The converse of Theorem 3.7 is not true in general as seen the following example.

Example 3.8. Let X := {1, a, b, c, d}, then X is a commutative BE-algebra with the following Cayley table:

Let F := {1, c, d}, then F is a mighty filter X. But it is not a positive implicative filter of X since c ∗ ((a ∗ b) ∗ a) = 1 ∈ F and c ∈ F, but a ∉ F.

Definition 3.9 ([11]). A soft set (f,X) of a BE-algebra X over U is called an int-soft positive implicative filter of X over U if it satisfies:

(IS1) f(x) ⊆ f(1);

(IS2) f(x ∗ ((y ∗ z) ∗ y)) ∩ f(x) ⊆ f(y) for all x, y, z ∈ X.

Every int-soft positive implicative filter of a BE-algebra X over U is an intsoft filter of X over U ([11]).

Theorem 3.10 ([11]). Let X be a BE-algebra. Then an int-soft filter (f,X) is an int-soft positive implicative filter of X if and only if

Theorem 3.11. Every int-soft positive implicative filter of a commutative BE-algebra X is an int-soft mighty filter of X.

Proof. Suppose (f,X) is an int-soft positive implicative filter. It follows from Theorem 3.7, y ∗ x ≤ ((((x ∗ y) ∗ y) ∗ x) ∗ x) ∗ (((x ∗ y) ∗ y) ∗ x). We have f(y ∗ x) ⊆ f(((((x ∗ y) ∗ y) ∗ x) ∗ x) ∗ (((x ∗ y) ∗ y) ∗ x)) ⊆ f(((x ∗ y) ∗ y) ∗ x) from Theorem 3.10. It satisfies Theorem 3.5. Hence (f,X) is an int-soft mighty filter of X. □

The converse of Theorem 3.11 does not hold in general as the following example.

Example 3.12. Let X := {1, a, b, c}, then X is a commutative BE-algebra with the following Cayley table:

Let a soft set (f,X) be defined as follows:

where γ1 and γ2 are subsets of U with , then (f,X) is an int-soft mighty filter of X. But it is not an int-soft positive implicative filter since f(1 ∗ ((b ∗ c) ∗ b)) ∩ f(1) = = f(b).

Theorem 3.13. Every int-soft mighty filter of a BE-algebra X is an int-soft positive implicative filter of X if it satisfies f((x∗ y) ∗x) ⊆ f(x) for all x, y ∈ X.

Proof. It is obvious from Theorem 3.10. □

 

4. Int-soft n-fold mighty filter and Int-soft n-fold positive implicative filter of a BE-algebra

In this chapter, we recall the definition of n-fold mighty filter F of a BE-algebra X in ([12]) which is satisfied two conditions: for all x, y, z ∈ X,

Let X be a BE-algebra and n denote a positive integer. For any elements x, y ∈ X, let f(xn ∗ y) denote f(x ∗ (x ∗ (· · ·(x ∗ y))) · ··).

Definition 4.1. A soft set (f,X) of a BE-algebra X is called an int-soft n-fold mighty filter of X if it satisfies:

(NM1) f(x) ⊆ f(1);

(NM2) f(x ∗ (y ∗ z)) ∩ f(x) ⊆ f(((zn ∗ y) ∗ y) ∗ z) for all x, y, z ∈ X.

Example 4.2. Let X be the set of parameters and U = X the universal set. Let X := {1, a, b, c, d}, then X is a BE-algebra with the following Cayley table:.

Let a soft set (f,X) be defined as follows:

where γ1 and γ2 are subsets of U with , then (f,X) is an int-soft n-fold mighty filter (n ≥ 2) of X.

Definition 4.3. A soft set (f,X) of a BE-algebra X over U is called an int-soft n-fold positive implicative filter of X if it satisfies:

(NP1) f(x) ⊆ f(1);

(NP2) f(x ∗ ((yn ∗ z) ∗ y)) ∩ f(x) ⊆ f(y) for all x, y, z ∈ X.

In Example 4.2, (f,X) is an int-soft n-fold positive implicative filter of a BE-algebra X.

Proposition 4.4. For a soft set (f,X) of a BE-algebra X,

Proof. (1) If we take y = 1 in (NM2),

Thus (f,X) is an int-soft filter of X.

(2) has the same way if we take z = 1 in (NP2). □

Theorem 4.5. Let (f,X) be an int-soft filter of a BE-algebra X. Then (f,X) is an int-soft n-fold mighty filter of X if and only if f(x∗y) ⊆ f(((yn ∗x)∗x)∗y) for all x, y, z ∈ X.

Proof. Suppose that (f,X) is an int-soft n-fold mighty filter of X.

For any x, y ∈ X, f(x∗y) = f(1∗(x∗y)) ⊆ f(1∗(x∗y))∩f(1) ⊆ f(((yn∗x)∗x)∗y). Conversely, assume (f,X) is an int-soft filter of X and it satisfies

then

Thus (f,X) is an int-soft n-fold mighty filter of X. □

Theorem 4.6. An int-soft filter (f,X) of a BE-algebra X is an int-soft n-fold positive implicative filter of X if and only if f((yn ∗ x) ∗ y) ⊆ f(y).

Proof. Suppose that (f,X) is an int-soft n-fold positive implicative filter of X. For any x, y ∈ X, f((yn ∗ x) ∗ y) ⊆ f(1 ∗ ((yn ∗ x) ∗ y)) ∩ f(1) ⊆ f(y), thus

Conversely, If (f,X) is an int-soft filter of X satisfying f((yn ∗ x) ∗ y) ⊆ f(y), then

Thus (f,X) is an int soft n-fold positive implicative filter of X. □

Proposition 4.7. For soft set (f,X) of a BE-algebra X,

(1) Every int-soft n-fold positive implicative filter of a commutative BE-algebra X is an int-soft n-fold mighty filter of X.

(2) Every int-soft n-fold mighty filter of a BE-algebra X is an int-soft n-fold positive implicative filter of X if it satisfies f((xn∗y)∗x) ⊂ f(x) for all x, y ∈ X.

Proof. It is obvious by Theorem 3.11, Theorem 3.13. □

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