Intuitionistic Falling Shadow Theory with Applications in BCK/BCI-Algebras

Jun, Young Bae; Song, Seok-Zun; Lee, Kyoung Ja

doi:10.3390/math6080138

Open AccessArticle

Intuitionistic Falling Shadow Theory with Applications in BCK/BCI-Algebras

by

Young Bae Jun

¹,

Seok-Zun Song

^2,*

and

Kyoung Ja Lee

³

¹

Department of Mathematics Education, Gyeongsang National University, Jinju 52828, Korea

²

Department of Mathematics, Jeju National University, Jeju 63243, Korea

³

Department of Mathematics Education, Hannam University, Daejeon 306-791, Korea

^*

Author to whom correspondence should be addressed.

Mathematics 2018, 6(8), 138; https://doi.org/10.3390/math6080138

Submission received: 24 July 2018 / Revised: 3 August 2018 / Accepted: 6 August 2018 / Published: 13 August 2018

Download Versions Notes

Abstract

:

Intuitionistic falling shadow is introduced, and applied to

B C K / B C I

-algebras. Falling intuitionistic subalgebra and falling intuitionistic ideal of

B C K / B C I

-algebras are introduced, and related properties are investigated. Relations between falling intuitionistic subalgebra and falling intuitionistic ideal are discussed. A characterization of falling intuitionistic ideal is established.

Keywords:

intuitionistic fuzzy subalgebra; intuitionistic fuzzy ideal; intuitionistic random set; intuitionistic falling shadow; falling intuitionistic subalgebra; falling intuitionistic ideal

MSC:

06F35; 03G25; 08A72

1. Introduction

Attanassov [1] introduced the concept of intuitionistic fuzzy set which is a generalization of the fuzzy set. Then, this notion has contributed several branches within the pure and applied sciences. Goodman [2] pointed out the equivalence of a fuzzy set and a class of random sets in the study of a unified treatment of uncertainty modeled by means of combining probability and fuzzy set theory. Wang and Sanchez [3] discussed the theory of falling shadows, and the mathematical structure of the theory of falling shadows is formulated in [4]. Tan et al. [5,6] established a theoretical approach to define a fuzzy inference relation and fuzzy set operations based on the theory of falling shadows. Jun and Park [7] considered a fuzzy subalgebra and a fuzzy ideal as the falling shadow of the cloud of the subalgebra and ideal. Jun and Kang [8] discussed fuzzy positive implicative ideals of

B C K

-algebras based on the theory of falling shadows.

In this manuscript, as a generalization of the concept of fuzzy random set and fuzzy falling shadow, we introduce the notion of intuitionistic random set and intuitionistic falling shadow. Using these notions, we also introduce the concept of falling intuitionistic subalgebra and falling intuitionistic ideal of

B C K / B C I

-algebras, and investigate related properties. We discuss relations between falling intuitionistic subalgebra and falling intuitionistic ideal. We establish a characterization of falling intuitionistic ideal.

2. Preliminaries

A

B C K / B C I

-algebra is introduced by K. Iséki (see [9,10]), and it is an important class of logical algebras.

By a

B C K / B C I

-algebra we mean a structure

(X; *, 0)

satisfying the following conditions:

(I): $(\forall a, b, c \in X)$ $(((a * b) * (a * c)) * (c * b) = 0),$
(II): $(\forall a, b \in X)$ $((a * (a * b)) * b = 0),$
(III): $(\forall a \in X)$ $(a * a = 0),$
(IV): $(\forall a, b \in X)$ $(a * b = 0, b * a = 0 \Rightarrow a = b) .$

If a

B C I

-algebra X satisfies the following identity:

(V): $(\forall a \in X)$ $(0 * a = 0),$

then X is called a

B C K

-algebra. Any

B C K / B C I

-algebra X satisfies the following conditions:

\begin{matrix} (\forall a \in X) (a * 0 = a), \end{matrix}

(1)

\begin{matrix} (\forall a, b, c \in X) (a \leq b \Rightarrow a * c \leq b * c, c * b \leq c * a), \end{matrix}

(2)

\begin{matrix} (\forall a, b, c \in X) ((a * b) * c = (a * c) * b) \end{matrix}

(3)

where

x \leq y

if and only if

x * y = 0 .

We say that a nonempty subset S in a

B C K / B C I

-algebra X is a subalgebra of X if

a * b \in S

for all

a, b \in S .

We say that a subset I of a

B C K / B C I

-algebra X is an ideal of X if it satisfies:

\begin{matrix} 0 \in I, \end{matrix}

(4)

\begin{matrix} (\forall a \in X) (\forall b \in I) (a * b \in I \Rightarrow a \in I) . \end{matrix}

(5)

We refer the reader to the books [11,12] for further information regarding

B C K / B C I

-algebras.

An intuitionistic fuzzy set

f = (f_{α}, f_{β})

in a

B C K / B C I

-algebra X is called an intuitionistic fuzzy subalgebra of X (see [13]) if it satisfies:

\begin{matrix} (\forall a, b \in X) (\begin{matrix} f_{α} (a * b) \geq min {f_{α} (a), f_{α} (b)} \\ f_{β} (a * b) \leq max {f_{β} (a), f_{β} (b)} \end{matrix}) . \end{matrix}

(6)

An intuitionistic fuzzy set

f = (f_{α}, f_{β})

in a

B C K / B C I

-algebra X is called an intuitionistic fuzzy ideal of X (see [13]) if it satisfies:

\begin{matrix} (\forall y \in X) (\begin{matrix} f_{α} (0) \geq f_{α} (y), f_{β} (0) \leq f_{β} (y) \end{matrix}) . \end{matrix}

(7)

\begin{matrix} (\forall a, b \in X) (\begin{matrix} f_{α} (a) \geq min {f_{α} (a * b), f_{α} (b)} \\ f_{β} (a) \leq max {f_{β} (a * b), f_{β} (b)} \end{matrix}) . \end{matrix}

(8)

For any

(t_{α}, t_{β}) \in [0, 1] \times [0, 1]

and an intuitionistic fuzzy set

f = (f_{α}, f_{β})

in a

B C K / B C I

-algebra X, consider the following sets:

\begin{matrix} U (f; t_{α}) = {x \in X ∣ f_{α} (x) \geq t_{α}} \end{matrix}

and

\begin{matrix} L (f; t_{β}) = {x \in X ∣ f_{β} (x) \leq t_{β}} . \end{matrix}

3. Intuitionistic Fuzzification of Subalgebras/Ideals Based on Intuitionistic Falling Shadows

Given a

B C K / B C I

-algebra X,

x \in X

and

D \in 2^{X}

, let

\begin{matrix} \bar{x} : = {C \in 2^{X} ∣ x \in C}, \end{matrix}

(9)

and

\begin{matrix} \bar{D} : = {\bar{x} ∣ x \in D} . \end{matrix}

(10)

An ordered pair

(2^{X}, B)

is said to be a hyper-measurable structure on X if

B

is a

σ

-field in

2^{X}

and

\bar{X} \subseteq B

.

Given a probability space

(Γ, A, P)

and a hyper-measurable structure

(2^{X}, B)

on X, an intuitionistic random set on X is defined to be a couple

ζ : = (ζ_{α}, ζ_{β})

in which

ζ_{α}

and

ζ_{β}

are mappings from

Γ

to

2^{X}

which are

A

-

B

measurables, that is,

\begin{matrix} (\forall C \in B) (\begin{matrix} ζ_{α}^{- 1} (C) = {ω_{α} \in Γ ∣ ζ_{α} (ω_{α}) \in C} \in A \\ ζ_{β}^{- 1} (C) = {ω_{β} \in Γ ∣ ζ_{β} (ω_{β}) \in C} \in A \end{matrix}) . \end{matrix}

(11)

Given an intuitionistic random set

ζ : = (ζ_{α}, ζ_{β})

on X, consider functions:

\begin{matrix} {\tilde{G}}_{α} : X \to [0, 1], x_{α} \mapsto P (ω_{α} ∣ x_{α} \in ζ_{α} (ω_{α})), \\ {\tilde{G}}_{β} : X \to [0, 1], x_{β} \mapsto 1 - P (ω_{β} ∣ x_{β} \in ζ_{β} (ω_{β})) . \end{matrix}

Then

\tilde{G} : = ({\tilde{G}}_{α}, {\tilde{G}}_{β})

is an intuitionistic fuzzy set on X, and we call it the intuitionistic falling shadow of the intuitionistic random set

ζ : = (ζ_{α}, ζ_{β})

, and

ζ : = (ζ_{α}, ζ_{β})

is called a intuitionistic cloud of

\tilde{G} : = ({\tilde{G}}_{α}, {\tilde{G}}_{β})

.

For example, consider a probability space

(Γ, A, P) = ([0, 1], A, m)

where

A

is a Borel field on

[0, 1]

and m is the usual Lebesgue measure. Let

\tilde{G} : = ({\tilde{G}}_{α}, {\tilde{G}}_{β})

be an intuitionistic fuzzy set in X. Then a couple

ζ : = (ζ_{α}, ζ_{β})

in which

\begin{matrix} ζ_{α} : [0, 1] \to 2^{X}, t_{α} \mapsto U (\tilde{G}; t_{α}), \\ ζ_{β} : [0, 1] \to 2^{X}, t_{β} \mapsto L (\tilde{G}; t_{β}) \end{matrix}

is an intuitionistic random set and

ζ : = (ζ_{α}, ζ_{β})

is an intuitionistic cloud of

\tilde{G} : = ({\tilde{G}}_{α}, {\tilde{G}}_{β})

. We will call

ζ : = (ζ_{α}, ζ_{β})

defined above as the intuitionistic cut-cloud of

\tilde{G} : = ({\tilde{G}}_{α}, {\tilde{G}}_{β})

.

Definition 1.

Let

(Γ, A, P)

be a probability space and let

ζ : = (ζ_{α}, ζ_{β})

be an intuitionistic random set on a

B C K / B C I

-algebra X. Then the intuitionistic falling shadow

\tilde{G} : = ({\tilde{G}}_{α}, {\tilde{G}}_{β})

of

ζ : = (ζ_{α}, ζ_{β})

is called a falling intuitionistic subalgebra (resp., falling intuitionistic ideal) of X if

ζ_{α} (ω_{α})

and

ζ_{β} (ω_{β})

are subalgebras (resp., ideals) of X for all

ω_{α},

ω_{β} \in Γ

.

Example 1.

Consider a set

X = {0, 1, 2, 3, 4}

with the binary operation ∗ which is given in Table 1.

Then

(X; *, 0)

is a

B C K

-algebra (see [12]). Let

ζ : = (ζ_{α}, ζ_{β})

be an intuitionistic random set on X which is given as follows:

\begin{matrix} ζ_{α} : [0, 1] \to 2^{X}, x \mapsto \{\begin{matrix} {0, 1} & if t \in [0, 0.3), \\ {0, 2} & if t \in [0.3, 0.7), \\ {0, 1, 2} & if t \in [0.7, 0.8), \\ X & if t \in [0.8, 1], \end{matrix} \end{matrix}

and

\begin{matrix} ζ_{β} : [0, 1] \to 2^{X}, x \mapsto \{\begin{matrix} {0} & if t \in (0.9, 1], \\ {0, 1} & if t \in (0.7, 0.9], \\ {0, 2} & if t \in (0.5, 0.7], \\ {0, 1, 2} & if t \in (0.3, 0.5], \\ X & if t \in [0, 0.3] . \end{matrix} \end{matrix}

Then

ζ_{α} (t)

and

ζ_{β} (t)

are subalgebras and ideals of X for all

t \in [0, 1]

. Hence the intuitionistic falling shadow

\tilde{G} : = ({\tilde{G}}_{α}, {\tilde{G}}_{β})

of

ζ : = (ζ_{α}, ζ_{β})

is a falling intuitionistic subalgebra and a falling intuitionistic ideal of X, and it is given as follows:

\begin{matrix} {\tilde{G}}_{α} (x) = \{\begin{matrix} 1 & if x = 0, \\ 0.6 & if x = 1, \\ 0.7 & if x = 2, \\ 0.2 & if x \in {3, 4}, \end{matrix} \end{matrix}

\begin{matrix} {\tilde{G}}_{β} (x) = \{\begin{matrix} 0 & if x = 0, \\ 0.3 & if x \in {1, 2}, \\ 0.7 & if x \in {3, 4} . \end{matrix} \end{matrix}

Let X be a

B C K / B C I

-algebra. Given a probability space

(Γ, A, P)

, let

\begin{matrix} F (X) : = {f ∣ f : Γ \to X is a mapping} . \end{matrix}

(12)

Define a binary operation ⊛ on

F (X)

as follows:

\begin{matrix} (\forall ω \in Γ) ((f ⊛ g) (ω) = f (ω) * g (ω)) \end{matrix}

(13)

for all

f, g \in F (X)

. Then

(F (X); ⊛, 0)

is a

B C K / B C I

-algebra (see [7]) where

0

is given as follows:

\begin{matrix} 0 : Γ \to X, ω \mapsto 0 . \end{matrix}

For any subset A of a

B C K / B C I

-algebra X and

g_{α},

g_{β} \in F (X)

, consider the following sets:

\begin{matrix} A_{α}^{g} : = {ω_{α} \in Γ ∣ g_{α} (ω_{α}) \in A}, \\ A_{β}^{g} : = {ω_{β} \in Γ ∣ g_{β} (ω_{β}) \in A} \end{matrix}

and

\begin{matrix} ζ_{α} : Γ \to 2^{F (X)}, ω_{α} \mapsto {g_{α} \in F (X) ∣ g_{α} (ω_{α}) \in A}, \\ ζ_{β} : Γ \to 2^{F (X)}, ω_{β} \mapsto {g_{β} \in F (X) ∣ g_{β} (ω_{β}) \in A} . \end{matrix}

Then

A_{α}^{g},

A_{β}^{g} \in A

.

Assume that A is a subalgebra (resp., ideal) of a

B C K / B C I

-algebra X and let

ω_{α},

ω_{β} \in Γ

. Since

0 (ω) = 0 \in A

for

ω \in {ω_{α}, ω_{β}}

, we know that

0 \in ζ_{α} (ω_{α})

and

0 \in ζ_{β} (ω_{β})

. For any

f_{α},

g_{α} \in F (X)

, if

f_{α},

g_{α} \in ζ_{α} (ω_{α})

, then

\begin{matrix} (f_{α} ⊛ g_{α}) (ω_{α}) = f_{α} (ω_{α}) * g_{α} (ω_{α}) \in A \end{matrix}

and so

f_{α} ⊛ g_{α} \in ζ_{α} (ω_{α})

. Thus

ζ_{α} (ω_{α})

is a subalgebra of

F (X)

for all

ω_{α} \in Γ

. If

f_{α} ⊛ g_{α} \in ζ_{α} (ω_{α})

and

g_{α} \in ζ_{α} (ω_{α}),

then

f_{α} (ω_{α}) * g_{α} (ω_{α}) = (f_{α} ⊛ g_{α}) (ω_{α}) \in A

and

g_{α} (ω_{α}) \in A

. Since A is an ideal of X, it follows that

f_{α} (ω_{α}) \in A

, i.e.,

f_{α} \in ζ_{α} (ω_{α})

. Hence

ζ_{α} (ω_{α})

is an ideal of

F (X)

for all

ω_{α} \in Γ

. By the similar way, we can verify that

ζ_{β} (ω_{β})

is a subalgebra (resp., ideal) of

F (X)

for all

ω_{β} \in Γ

. Since

\begin{matrix} ζ_{α}^{- 1} ({\bar{g}}_{α}) = {ω_{α} \in Γ ∣ g_{α} \in ζ_{α} (ω_{α})} = {ω_{α} \in Γ ∣ g_{α} (ω_{α}) \in A} = A_{α}^{g} \in A, \\ ζ_{β}^{- 1} ({\bar{g}}_{β}) = {ω_{β} \in Γ ∣ g_{β} \in ζ_{β} (ω_{β})} = {ω_{β} \in Γ ∣ g_{β} (ω_{β}) \in A} = A_{β}^{g} \in A, \end{matrix}

ζ : = (ζ_{α}, ζ_{β})

is an intuitionistic random set on

F (X)

. Hence

\tilde{G} : = ({\tilde{G}}_{α}, {\tilde{G}}_{β})

is a falling intuitionistic subalgebra and a falling intuitionistic ideal of

F (X)

where

\begin{matrix} {\tilde{G}}_{α} : F (X) \to [0, 1], g_{α} \mapsto P (ω_{α} ∣ g_{α} (ω_{α}) \in A), \\ {\tilde{G}}_{α} : F (X) \to [0, 1], g_{β} \mapsto 1 - P (ω_{β} ∣ g_{β} (ω_{β}) \in A) . \end{matrix}

Given a probability space

(Γ, A, P)

, let

\tilde{G} : = ({\tilde{G}}_{α}, {\tilde{G}}_{β})

be an intuitionistic falling shadow of an intuitionistic random set

ζ : = (ζ_{α}, ζ_{β})

. For an element x of a

B C K / B C I

-algebra X, let

\begin{matrix} Γ (x; ζ_{α}) : = {ω_{α} \in Γ ∣ x \in ζ_{α} (ω_{α})}, \\ Γ (x; ζ_{β}) : = {ω_{β} \in Γ ∣ x \in ζ_{β} (ω_{β})} . \end{matrix}

Then

Γ (x; ζ_{α}) \in A

and

Γ (x; ζ_{β}) \in A

.

Proposition 1.

Let

\tilde{G} : = ({\tilde{G}}_{α}, {\tilde{G}}_{β})

be an intuitionistic falling shadow of the intuitionistic random set

ζ : = (ζ_{α}, ζ_{β})

. If

\tilde{G} : = ({\tilde{G}}_{α}, {\tilde{G}}_{β})

is a falling intuitionistic subalgebra of a

B C K / B C I

-algebra X, then

\begin{matrix} (\forall x, y \in X) (\begin{matrix} Γ (x; ζ_{α}) \cap Γ (y; ζ_{α}) \subseteq Γ (x * y; ζ_{α}) \\ Γ (x; ζ_{β}) \cap Γ (y; ζ_{β}) \subseteq Γ (x * y; ζ_{β}) \end{matrix}) . \end{matrix}

(14)

If

\tilde{G} : = ({\tilde{G}}_{α}, {\tilde{G}}_{β})

is a falling intuitionistic ideal of a

B C K / B C I

-algebra X, then

\begin{matrix} (\forall x, y \in X) (x \leq y \Rightarrow \{\begin{matrix} Γ (y; ζ_{α}) \subseteq Γ (x; ζ_{α}) \\ Γ (y; ζ_{β}) \subseteq Γ (x; ζ_{β}) \end{matrix}), \end{matrix}

(15)

\begin{matrix} (\forall x, y \in X) (\begin{matrix} Γ (x * y; ζ_{α}) \cap Γ (y; ζ_{α}) \subseteq Γ (x; ζ_{α}) \\ Γ (x * y; ζ_{β}) \cap Γ (y; ζ_{β}) \subseteq Γ (x; ζ_{β}) \end{matrix}) . \end{matrix}

(16)

If

\tilde{G} : = ({\tilde{G}}_{α}, {\tilde{G}}_{β})

is a falling intuitionistic ideal/subalgebra of a

B C K

-algebra X, then

\begin{matrix} (\forall x \in X) (\begin{matrix} Γ (x; ζ_{α}) \subseteq Γ (0; ζ_{α}) \\ Γ (x; ζ_{β}) \subseteq Γ (0; ζ_{β}) \end{matrix}) . \end{matrix}

(17)

If

\tilde{G} : = ({\tilde{G}}_{α}, {\tilde{G}}_{β})

is a falling intuitionistic ideal of a

B C K

-algebra X, then

\begin{matrix} (\forall x, y \in X) (\begin{matrix} Γ (x; ζ_{α}) \subseteq Γ (x * y; ζ_{α}) \\ Γ (x; ζ_{β}) \subseteq Γ (x * y; ζ_{β}) \end{matrix}) . \end{matrix}

(18)

Proof.

Assume that

\tilde{G} : = ({\tilde{G}}_{α}, {\tilde{G}}_{β})

is a falling intuitionistic subalgebra of X. If

ω_{α} \in Γ (x; ζ_{α}) \cap Γ (y; ζ_{α})

for any

x, y \in X

, then

x \in ζ_{α} (ω_{α})

and

y \in ζ_{α} (ω_{α})

. Since

ζ_{α} (ω_{α})

is a subalgebra of X, it follows that

x * y \in ζ_{α} (ω_{α})

, that is,

ω_{α} \in Γ (x * y; ζ_{α})

. Now let

ω_{β} \in Γ (x; ζ_{β}) \cap Γ (y; ζ_{β})

for any

x, y \in X

. Then

x \in ζ_{β} (ω_{β})

and

y \in ζ_{β} (ω_{β})

, which imply that

x * y \in ζ_{β} (ω_{β})

since

ζ_{β} (ω_{β})

is a subalgebra of X. Hence

ω_{β} \in Γ (x * y; ζ_{β})

, and therefore Equation (14) holds. Suppose that

\tilde{G} : = ({\tilde{G}}_{α}, {\tilde{G}}_{β})

is a falling intuitionistic ideal of X and let

x, y \in X

be such that

x \leq y

. Then

x * y = 0

. If

ω_{α} \in Γ (y; ζ_{α})

, then

y \in ζ_{α} (ω_{α})

and

x * y = 0 \in ζ_{α} (ω_{α})

. Thus

x \in ζ_{α} (ω_{α})

since

ζ_{α} (ω_{α})

is an ideal of X. Hence

ω_{α} \in Γ (x; ζ_{α})

, and so

Γ (y; ζ_{α}) \subseteq Γ (x; ζ_{α})

. Let

ω_{β} \in Γ (y; ζ_{β})

. Then

y \in ζ_{β} (ω_{β})

and

x * y = 0 \in ζ_{β} (ω_{β})

, which imply that

x \in ζ_{β} (ω_{β})

since

ζ_{β} (ω_{β})

is an ideal of X. Hence

ω_{β} \in Γ (x; ζ_{β})

which shows that

Γ (y; ζ_{β}) \subseteq Γ (x; ζ_{β})

. The inclusions

Γ (x * y; ζ_{α}) \cap Γ (y; ζ_{α}) \subseteq Γ (x; ζ_{α})

and

Γ (x * y; ζ_{β}) \cap Γ (y; ζ_{β}) \subseteq Γ (x; ζ_{β})

are obtained by the similarly way . Please note that

0 \leq x

and

x * y \leq x

in a

B C K

-algebra. Hence the result Equation (15) induces Equations (17) and (18).

Theorem 1.

Let X be a

B C K / B C I

-algebra. If we take a probability space

(Γ, A, P) = ([0, 1], A, m)

, then every intuitionistic fuzzy subalgebra (resp., intuitionistic fuzzy ideal) of X is a falling intuitionistic subalgebra (resp., falling intuitionistic ideal) of X.

Proof.

Let

\tilde{G} : = ({\tilde{G}}_{α}, {\tilde{G}}_{β})

be an intuitionistic fuzzy subalgebra (resp., intuitionistic fuzzy ideal) of a

B C K / B C I

-algebra X. Then

U (\tilde{G}; t_{α})

and

L (\tilde{G}; t_{β})

are subalgebras (resp., ideals) of X for all

(t_{α}, t_{β}) \in [0, 1] \times [0, 1]

. Hence a couple

ζ : = (ζ_{α}, ζ_{β})

in which

\begin{matrix} ζ_{α} : [0, 1] \to 2^{X}, t_{α} \mapsto U (\tilde{G}; t_{α}), \\ ζ_{β} : [0, 1] \to 2^{X}, t_{β} \mapsto L (\tilde{G}; t_{β}) \end{matrix}

is an intuitionistic cut-cloud of

\tilde{G} : = ({\tilde{G}}_{α}, {\tilde{G}}_{β})

, and so

\tilde{G} : = ({\tilde{G}}_{α}, {\tilde{G}}_{β})

is a falling intuitionistic subalgebra (resp., falling intuitionistic ideal) of X. ☐

The converse of Theorem 1 is not true as seen in the following example.

Example 2.

Consider a set

X = {0, a, b, c}

with the binary operation ∗ which is given in Table 2.

Then

(X; *, 0)

is a

B C I

-algebra (see [12]). Consider

(Γ, A, P) = ([0, 1], A, m)

as a probability space, and let

ζ : = (ζ_{α}, ζ_{β})

be an intuitionistic random set on X which is given as follows:

\begin{matrix} ζ_{α} : [0, 1] \to 2^{X}, x \mapsto \{\begin{matrix} {0} & if t \in [0, 0.2), \\ {0, a} & if t \in [0.2, 0.7), \\ {0, b} & if t \in [0.7, 0.8), \\ X & if t \in [0.8, 1], \end{matrix} \end{matrix}

and

\begin{matrix} ζ_{β} : [0, 1] \to 2^{X}, x \mapsto \{\begin{matrix} {0} & if t \in (0.8, 1], \\ {0, a} & if t \in (0.7, 0.8], \\ {0, b} & if t \in (0.5, 0.7], \\ {0, c} & if t \in [0, 0.5] . \end{matrix} \end{matrix}

Then

ζ_{α} (t)

and

ζ_{β} (t)

are subalgebras of X for all

t \in [0, 1]

. Hence the intuitionistic falling shadow

\tilde{G} : = ({\tilde{G}}_{α}, {\tilde{G}}_{β})

of

ζ : = (ζ_{α}, ζ_{β})

is a falling intuitionistic subalgebra of X, and it is given as follows:

\begin{matrix} {\tilde{G}}_{α} (x) = \{\begin{matrix} 1 & if x = 0, \\ 0.7 & if x = a, \\ 0.3 & if x = b, \\ 0.2 & if x = c, \end{matrix} \end{matrix}

and

\begin{matrix} {\tilde{G}}_{β} (x) = \{\begin{matrix} 0 & if x = 0, \\ 0.9 & if x = a, \\ 0.8 & if x = b, \\ 0.5 & if x = c . \end{matrix} \end{matrix}

Since

{\tilde{G}}_{β} (b * c) = {\tilde{G}}_{β} (a) = 0.9 > 0.8 = max {{\tilde{G}}_{β} (b), {\tilde{G}}_{β} (c)}

, we know that

\tilde{G} : = ({\tilde{G}}_{α}, {\tilde{G}}_{β})

is not an intuitionistic fuzzy subalgebra of X.

If we take an intuitionistic random set

ζ : = (ζ_{α}, ζ_{β})

on X as follows:

\begin{matrix} ζ_{α} : [0, 1] \to 2^{X}, x \mapsto \{\begin{matrix} {0, a} & if t \in [0, 0.3), \\ {0, b} & if t \in [0.3, 0.5), \\ {0, c} & if t \in [0.5, 1], \end{matrix} \end{matrix}

and

\begin{matrix} ζ_{β} : [0, 1] \to 2^{X}, x \mapsto \{\begin{matrix} {0} & if t \in (0.8, 1], \\ {0, a} & if t \in (0.7, 0.8], \\ {0, b} & if t \in (0.5, 0.7], \\ {0, c} & if t \in [0, 0.5] . \end{matrix} \end{matrix}

Then

ζ_{α} (t)

and

ζ_{β} (t)

are ideals of X for all

t \in [0, 1]

. Hence the intuitionistic falling shadow

\tilde{G} : = ({\tilde{G}}_{α}, {\tilde{G}}_{β})

of

ζ : = (ζ_{α}, ζ_{β})

is a falling intuitionistic ideal of X, and it is given as follows:

\begin{matrix} {\tilde{G}}_{α} (x) = \{\begin{matrix} 1 & if x = 0, \\ 0.3 & if x = a, \\ 0.2 & if x = b, \\ 0.5 & if x = c, \end{matrix} \end{matrix}

and

\begin{matrix} {\tilde{G}}_{β} (x) = \{\begin{matrix} 0 & if x = 0, \\ 0.9 & if x = a, \\ 0.8 & if x = b, \\ 0.5 & if x = c . \end{matrix} \end{matrix}

Since

{\tilde{G}}_{α} (b) = 0.2 < 0.3 = min {{\tilde{G}}_{α} (b * a), {\tilde{G}}_{α} (a)}

, we know that

\tilde{G} : = ({\tilde{G}}_{α}, {\tilde{G}}_{β})

is not an intuitionistic fuzzy ideal of X.

Theorem 2.

If we take a probability space

(Γ, A, P) = ([0, 1], A, m)

, then every falling intuitionistic ideal is a falling intuitionistic subalgebra in a

B C K

-algebra.

Proof.

Since every ideal is a subalgebra in a

B C K

-algebra, it is straightforward. ☐

The following example shows that Theorem 2 is not true in a

B C I

-algebra.

Example 3.

Let X be the set of all nonzero rational numbers. If we take a binary operation ∗ on X defined by division as general, then

(X; *, 1)

is a

B C I

-algebra (see [14]). Consider

(Γ, A, P) = ([0, 1], A, m)

as a probability space, and let

ζ : = (ζ_{α}, ζ_{β})

be an intuitionistic random set on X which is given as follows:

\begin{matrix} ζ_{α} : [0, 1] \to 2^{X}, x \mapsto \{\begin{matrix} X & if t \in (0.6, 1], \\ Z^{*} & if t \in [0, 0.6], \end{matrix} \end{matrix}

and

\begin{matrix} ζ_{β} : [0, 1] \to 2^{X}, x \mapsto \{\begin{matrix} X & if t \in [0, 0.7), \\ Z^{*} & if t \in [0.7, 1], \end{matrix} \end{matrix}

where

Z^{*}

is the set of all nonzero integers. Then the intuitionistic falling shadow

\tilde{G} : = ({\tilde{G}}_{α}, {\tilde{G}}_{β})

of

ζ : = (ζ_{α}, ζ_{β})

is a falling intuitionistic ideal of X, but it is not a falling intuitionistic subalgebra of X because

ζ_{α} (0.4) = Z^{*}

and/or

ζ_{β} (0.85) = Z^{*}

are not subalgebras of X since

2 \in Z^{*}

and

3 \in Z^{*}

but

2 * 3 \notin Z^{*}

.

We provide conditions for a falling intuitionistic subalgebra to be a falling intuitionistic ideal in

B C I

-algebras.

Theorem 3.

Given a

B C I

-algebra X, assume that the intuitionistic falling shadow

\tilde{G} : = ({\tilde{G}}_{α}, {\tilde{G}}_{β})

of an intuitionistic random set

ζ : = (ζ_{α}, ζ_{β})

is a falling intuitionistic subalgebra of X. Then

\tilde{G} : = ({\tilde{G}}_{α}, {\tilde{G}}_{β})

is a falling intuitionistic ideal of X if and only if for every

x, y \in X

and

ω_{α},

ω_{β} \in Γ

, the following conditions are valid:

\begin{matrix} \begin{matrix} x \in ζ_{α} (ω_{α}), y \notin ζ_{α} (ω_{α}) \Rightarrow y * x \notin ζ_{α} (ω_{α}), \\ x \in ζ_{β} (ω_{β}), y \notin ζ_{α} (ω_{β}) \Rightarrow y * x \notin ζ_{β} (ω_{β}) . \end{matrix} \end{matrix}

(19)

Proof.

If

\tilde{G} : = ({\tilde{G}}_{α}, {\tilde{G}}_{β})

is a falling intuitionistic ideal of a

B C I

-algebra X, then

ζ_{α} (ω_{α})

and

ζ_{β} (ω_{β})

are ideals of X for all

ω_{α},

ω_{β} \in Γ

. Let

x, y \in X

be such that

x \in ζ_{α} (ω_{α})

and

y \notin ζ_{α} (ω_{α})

. If

y * x \in ζ_{α} (ω_{α})

, then

y \in ζ_{α} (ω_{α})

since

ζ_{α} (ω_{α})

is an ideal of X. Hence

y * x \notin ζ_{α} (ω_{α})

. Similarly, if

x \in ζ_{β} (ω_{β})

and

y \notin ζ_{β} (ω_{β})

, then

y * x \notin ζ_{β} (ω_{β})

.

Conversely, let

\tilde{G} : = ({\tilde{G}}_{α}, {\tilde{G}}_{β})

be a falling intuitionistic subalgebra of a

B C I

-algebra X that satisfies the condition Equation (19). Then

ζ_{α} (ω_{α})

and

ζ_{β} (ω_{β})

are subalgebras of X for all

ω_{α},

ω_{β} \in Γ

. Hence 0 is contained in

ζ_{α} (ω_{α})

and

ζ_{β} (ω_{β})

. Let

x,

y,

c,

d \in X

be such that

x * y \in ζ_{α} (ω_{α})

,

y \in ζ_{α} (ω_{α})

,

c * d \in ζ_{β} (ω_{β})

and

d \in ζ_{β} (ω_{β})

. If

x \notin ζ_{α} (ω_{α})

(resp.,

c \notin ζ_{β} (ω_{β})

), then

x * y \notin ζ_{α} (ω_{α})

(resp.,

c * d \notin ζ_{β} (ω_{β})

) by Equation (19). This is a contradiction, and so

x \in ζ_{α} (ω_{α})

and

c \in ζ_{β} (ω_{β})

. Therefore

\tilde{G} : = ({\tilde{G}}_{α}, {\tilde{G}}_{β})

is a falling intuitionistic ideal of X. ☐

4. Conclusions

As a general concept of the fuzzy random set and fuzzy falling shadow, we have considered the concepts of intuitionistic random set and intuitionistic falling shadow. Using these generalized notions, we have introduced the notion of falling intuitionistic subalgebra and falling intuitionistic ideal of

B C K / B C I

-algebras. We have discussed relations between falling intuitionistic subalgebra and falling intuitionistic ideal, and have established a characterization of falling intuitionistic ideal.

Author Contributions

This paper is a result of common work of the authors in all aspects.

Funding

This research received no external funding.

Acknowledgments

The authors wish to thank the anonymous reviewers for their valuable comments and suggestions. The second author was supported under the framework of international cooperation program managed by the National Research Foundation of Korea (2017 K2A9A1A01092970, FY2017).

Conflicts of Interest

The authors declare no conflict of interest.

References

Atanassov, K.T. Intuitionistic fuzzy sets. Fuzzy Sets Syst. 1986, 20, 87–96. [Google Scholar] [CrossRef]
Goodman, I.R. Fuzzy sets as equivalence classes of random sets. In Recent Developments in Fuzzy Sets and Possibility Theory; Yager, R., Ed.; Pergamon: New York, NY, USA, 1982; pp. 327–343. [Google Scholar]
Wang, P.Z.; Sanchez, E. Treating a fuzzy subset as a projectable random set. In Fuzzy Information and Decision; Gupta, M.M., Sanchez, E., Eds.; Pergamon: New York, NY, USA, 1982; pp. 212–219. [Google Scholar]
Wang, P.Z. Fuzzy Sets and Falling Shadows of Random Sets; Beijing Normal Univ. Press: Beijing, China, 1985. (In Chinese) [Google Scholar]
Tan, S.K.; Wang, P.Z.; Lee, E.S. Fuzzy set operations based on the theory of falling shadows. J. Math. Anal. Appl. 1993, 174, 242–255. [Google Scholar] [CrossRef]
Tan, S.K.; Wang, P.Z.; Zhang, X.Z. Fuzzy inference relation based on the theory of falling shadows. Fuzzy Sets Syst. 1993, 53, 179–188. [Google Scholar] [CrossRef]
Jun, Y.B.; Park, C.H. Falling shadows applied to subalgebras and ideals of BCK/BCI-algebras. Honam Math. J. 2012, 34, 135–144. [Google Scholar] [CrossRef]
Jun, Y.B.; Kang, M.S. Fuzzy positive implicative ideals of BCK-algebras based on the theory of falling shadows. Comput. Math. Appl. 2011, 61, 62–67. [Google Scholar] [CrossRef]
Iséki, K. On BCI-algebras. Math. Semin. Notes 1980, 8, 125–130. [Google Scholar]
Iséki, K.; Tanaka, S. An introduction to the theory of BCK-algebras. Math. Jpn. 1978, 23, 1–26. [Google Scholar]
Huang, Y. BCI-Algebra; Science Press: Beijing, China, 2006. [Google Scholar]
Meng, J.; Jun, Y.B. BCK-Algebras; Kyungmoon Sa Co.: Seoul, Korea, 1994. [Google Scholar]
Jun, Y.B.; Kim, K.H. Intuitionistic fuzzy ideals of BCK-algebras. Int. J. Math. Math. Sci. 2000, 24, 839–849. [Google Scholar] [CrossRef]
Chen, Z.M.; Wang, H.X. On ideals in BCI-algebras. Math. Jpn. 1991, 36, 497–501. [Google Scholar]

Table 1. Cayley table for the binary operation “∗”.

*	0	1	2	3
0	0	0	0	0
1	1	0	1	0
2	2	2	0	0
3	3	3	3	0
4	4	3	4	1

Table 2. Cayley table for the binary operation “∗”.

*	0	a	b	c
0	0	a	b	c
a	a	0	c	b
b	b	c	0	a
c	c	b	a	0

© 2018 by the authors. Licensee MDPI, Basel, Switzerland. This article is an open access article distributed under the terms and conditions of the Creative Commons Attribution (CC BY) license (http://creativecommons.org/licenses/by/4.0/).

Share and Cite

MDPI and ACS Style

Jun, Y.B.; Song, S.-Z.; Lee, K.J. Intuitionistic Falling Shadow Theory with Applications in BCK/BCI-Algebras. Mathematics 2018, 6, 138. https://doi.org/10.3390/math6080138

AMA Style

Jun YB, Song S-Z, Lee KJ. Intuitionistic Falling Shadow Theory with Applications in BCK/BCI-Algebras. Mathematics. 2018; 6(8):138. https://doi.org/10.3390/math6080138

Chicago/Turabian Style

Jun, Young Bae, Seok-Zun Song, and Kyoung Ja Lee. 2018. "Intuitionistic Falling Shadow Theory with Applications in BCK/BCI-Algebras" Mathematics 6, no. 8: 138. https://doi.org/10.3390/math6080138

APA Style

Jun, Y. B., Song, S. -Z., & Lee, K. J. (2018). Intuitionistic Falling Shadow Theory with Applications in BCK/BCI-Algebras. Mathematics, 6(8), 138. https://doi.org/10.3390/math6080138

Note that from the first issue of 2016, this journal uses article numbers instead of page numbers. See further details here.

Article Menu

Intuitionistic Falling Shadow Theory with Applications in BCK/BCI-Algebras

Abstract

1. Introduction

2. Preliminaries

3. Intuitionistic Fuzzification of Subalgebras/Ideals Based on Intuitionistic Falling Shadows

4. Conclusions

Author Contributions

Funding

Acknowledgments

Conflicts of Interest

References

Share and Cite

Article Metrics

Article Access Statistics

Further Information

Guidelines

MDPI Initiatives

Follow MDPI