Home Mathematics MBJ-neutrosophic ideals of BCK/BCI-algebras
Article Open Access

MBJ-neutrosophic ideals of BCK/BCI-algebras

  • Young Bae Jun and Eun Hwan Roh EMAIL logo
Published/Copyright: November 28, 2019
Download Article (PDF)
Open Mathematics
From the journal Open Mathematics Volume 17 Issue 1

Abstract

The notion of MBJ-neutrosophic ideal is introduced, and its properties are investigated. Conditions for an MBJ-neutrosophic set to be an MBJ-neutrosophic ideal are provided. In a BCK/BCI-algebra, a condition for an MBJ-neutrosophic set to be an MBJ-neutrosophic ideal is given. In a BCK-algebra, a condition for an MBJ-neutrosophic subalgebra to be an MBJ-neutrosophic ideal is given. In a BCI-algebra, conditions for an MBJ-neutrosophic ideal to be an MBJ-neutrosophic subalgebra are considered. In an (S)-BCK-algebra, we show that every MBJ-neutrosophic ideal is an MBJ-neutrosophic ∘-subalgebra, and a characterization of an MBJ-neutrosophic ideal is established.

Keywords: MBJ-neutrosophic set; MBJ-neutrosophic subalgebra; MBJ-neutrosophic ideal; MBJ-neutro-sophic ∘-subalgebra
MSC 2010: 06F35; 03G25; 03E72

1 Introduction

Different types of uncertainties are encountered in many complex systems and/or in many practical situations like behavioral, biologial and chemical etc. In order to handle uncertainties in many real applications, the fuzzy set was introduced by L.A. Zadeh [1] in 1965. The intuitionistic fuzzy set on a universe X was introduced by K. Atanassov in 1983 as a generalization of fuzzy set. As a more general platform that extends the notions of classic set, (intuitionistic) fuzzy set and interval valued (intuitionistic) fuzzy set, the notion of neutrosophic set is developed by Smarandache [2, 3, 4]. Neutrosophic algebraic structures in BCK/BCI-algebras are discussed in the papers [5, 6, 7, 8, 9, 10, 11, 12, 13, 14] and [15]. In [16], the notion of MBJ-neutrosophic sets is introduced as another generalization of neutrosophic set, it is applied to BCK/BCI-algebras. Mohseni et al. [16] introduced the concept of MBJ-neutrosophic subalgebras in BCK/BCI-algebras, and investigated related properties. They gave a characterization of MBJ-neutrosophic subalgebra, and established a new MBJ-neutrosophic subalgebra by using an MBJ-neutrosophic subalgebra of a BCI-algebra. They considered the homomorphic inverse image of MBJ-neutrosophic subalgebra, and discussed translation of MBJ-neutrosophic subalgebra.

In this paper, we apply the notion of MBJ-neutrosophic sets to ideals of BCK/BI-algebras. We introduce the concept of MBJ-neutrosophic ideals in BCK/BCI-algebras, and investigate several properties. We provide a condition for an MBJ-neutrosophic subalgebra to be an MBJ-neutrosophic ideal in a BCK-algebra. We provide conditions for an MBJ-neutrosophic set to be an MBJ-neutrosophic ideal in a BCK/BCI-algebra. We discuss relations between MBJ-neutrosophic subalgebras, MBJ-neutrosophic ∘-subalgebras and MBJ-neutrosophic ideals. In a BCI-algebra, we provide conditions for an MBJ-neutrosophic ideal to be an MBJ-neutrosophic subalgebra. In an (S)-BCK-algebra, we consider a characterization of an MBJ-neutrosophic ideal.

2 Preliminaries

By a BCI-algebra, we mean a set X with a binary operation * and a special element 0 that satisfies the following conditions:

  1. ((x * y) * (x * z)) * (z * y) = 0,

  2. (x * (x * y)) * y = 0,

  3. x * x = 0,

  4. x * y = 0, y * x = 0 ⇒ x = y

for all x, y, zX. If a BCI-algebra X satisfies the following identity:

(V) (∀xX) (0 * x = 0),

then X is called a BCK-algebra.

By a weakly BCK-algebra (see [17]), we mean a BCI-algebra X satisfying 0 * xx for all xX.

Every BCK/BCI-algebra X satisfies the following conditions:

(xX)x0=x, (2.1)
(x,y,zX)xyxzyz,zyzx, (2.2)
(x,y,zX)(xy)z=(xz)y, (2.3)
(x,y,zX)(xz)(yz)xy, (2.4)

where xy if and only if x * y = 0. Any BCI-algebra X satisfies the following conditions (see [17]):

(x,yX)(x(x(xy))=xy), (2.5)
(x,yX)(0(xy)=(0x)(0y)). (2.6)

A BCI-algebra X is said to be p-semisimple (see [17]) if

(xX)(0(0x)=x). (2.7)

In a p-semisimple BCI-algebra X, the following holds:

(x,yX)(0(xy)=yx,x(xy)=y). (2.8)

A BCI-algebra X is said to be associative (see [17]) if

(x,y,zX)((xy)z=x(yz)). (2.9)

By an (S)-BCK-algebra, we mean a BCK-algebra X such that, for any x, yX, the set

{zXzxy}

has the greatest element, written by xy (see [18]).

A nonempty subset S of a BCK/BCI-algebra X is called a subalgebra of X if x * yS for all x, yS. A subset I of a BCK/BCI-algebra X is called an ideal of X if it satisfies:

0I, (2.10)
(xX)yIxyIxI. (2.11)

A subset I of a BCI-algebra X is called a closed ideal of X (see [17]) if it is an ideal of X which satisfies:

(xX)(xI0xI). (2.12)

By an interval number we mean a closed subinterval ã = [a, a+] of I, where 0 ≤ aa+ ≤ 1. Denote by [I] the set of all interval numbers. Let us define what is known as refined minimum (briefly, rmin) and refined maximum (briefly, rmax) of two elements in [I]. We also define the symbols “⪰”, “⪯”, “ = ” in case of two elements in [I]. Consider two interval numbers a~1:=a1,a1+ and a~2:=a2,a2+. Then

rmina~1,a~2=mina1,a2,mina1+,a2+,rmaxa~1,a~2=maxa1,a2,maxa1+,a2+,a~1a~2a1a2,a1+a2+,

and similarly we may have ã1ã2 and ã1 = ã2. To say ã1ã2 (resp. ã1ã2) we mean ã1ã2 and ã1ã2 (resp. ã1ã2 and ã1ã2). Let ãi ∈ [I] where iΛ. We define

rinfiΛa~i=infiΛai,infiΛai+andrsupiΛa~i=supiΛai,supiΛai+.

Let X be a nonempty set. A function A : X → [I] is called an interval-valued fuzzy set (briefly, an IVF set) in X. Let [I]X stand for the set of all IVF sets in X. For every A ∈ [I]X and xX, A(x) = [A(x), A+(x)] is called the degree of membership of an element x to A, where A : XI and A+ : XI are fuzzy sets in X which are called a lower fuzzy set and an upper fuzzy set in X, respectively. For simplicity, we denote A = [A, A+].

Let X be a non-empty set. A neutrosophic set (NS) in X (see [3]) is a structure of the form:

A:={x;AT(x),AI(x),AF(x)xX},

where AT : X → [0, 1] is a truth membership function, AI : X → [0, 1] is an indeterminate membership function, and AF : X → [0, 1] is a false membership function. For the sake of simplicity, we shall use the symbol A = (AT, AI, AF) for the neutrosophic set

A:={x;AT(x),AI(x),AF(x)xX}.

We refer the reader to the books [17, 18] for further information regarding BCK/BCI-algebras, and to the site “http://fs.gallup.unm.edu/neutrosophy.htm” for further information regarding neutrosophic set theory.

Let X be a non-empty set. By an MBJ-neutrosophic set in X (see [16]), we mean a structure of the form:

A:={x;MA(x),B~A(x),JA(x)xX},

where MA and JA are fuzzy sets in X, which are called a truth membership function and a false membership function, respectively, and A is an IVF set in X which is called an indeterminate interval-valued membership function.

For the sake of simplicity, we shall use the symbol 𝓐 = (MA, A, JA) for the MBJ-neutrosophic set

A:={x;MA(x),B~A(x),JA(x)xX}.

Let X be a BCK/BCI-algebra. An MBJ-neutrosophic set 𝓐 = (MA, A, JA) in X is called an MBJ-neutrosophic subalgebra of X (see [16]) if it satisfies:

(x,yX)MA(xy)min{MA(x),MA(y)},B~A(xy)rmin{B~A(x),B~A(y)},JA(xy)max{JA(x),JA(y)}. (2.13)

3 MBJ-neutrosophic ideals of BCK/BCI-algebras

Definition 3.1

Let X be a BCK/BCI-algebra. An MBJ-neutrosophic set 𝓐 = (MA, A, JA) in X is called an MBJ-neutrosophic ideal of X if it satisfies:

(xX)MA(0)MA(x)B~A(0)B~A(x)JA(0)JA(x) (3.1)

and

(x,yX)MA(x)min{MA(xy),MA(y)}B~A(x)rmin{B~A(xy),B~A(y)}JA(x)max{JA(xy),JA(y)}. (3.2)

An MBJ-neutrosophic ideal 𝓐 = (MA, A, JA) of a BCI-algebra X is said to be closed if

(xX)MA(0x)MA(x)B~A(0x)B~A(x)JA(0x)JA(x). (3.3)

Example 3.2

Consider a set X = {0, 1, 2, a} with the binary operation * which is given in Table 1. Then (X; *, 0) is a BCI-algebra (see [17]). Let 𝓐 = (MA, A, JA) be an MBJ-neutrosophic set in X defined by Table 2.

Table 1

Cayley table for the binary operation “*”.

* 0 1 2 a
0 0 0 0 a
1 1 0 0 a
2 2 2 0 a
a a a a 0

Table 2

MBJ-neutrosophic set 𝓐 = (MA, A, JA).

X MA(x) A(x) JA(x)
0 0.7 [1.0, 1.0] 0.2
1 0.5 [0.2, 0.6] 0.2
2 0.4 [0.2, 0.6] 0.7
a 0.3 [0.2, 0.6] 0.7

It is routine to verify that 𝓐 = (MA, A, JA) is a closed MBJ-neutrosophic ideal of X.

Proposition 3.3

Let X be a BCK/BCI-algebra. Then every MBJ-neutrosophic ideal 𝓐 = (MA, A, JA) of X satisfies the following assertion.

xyzMA(x)min{MA(y),MA(z)},B~A(x)rmin{B~A(y),B~A(z)},JA(x)max{JA(y),JA(z)} (3.4)

for all x, y, zX.

Proof

Let x, y, zX be such that x * yz. Then

MA(xy)min{MA((xy)z),MA(z)}=min{MA(0),MA(z)}=MA(z),B~A(xy)rmin{B~A((xy)z),B~A(z)}=rmin{B~A(0),B~A(z)}=B~A(z),

and

JA(xy)max{JA((xy)z),JA(z)}=max{JA(0),JA(z)}=JA(z).

It follows that

MA(x)min{MA(xy),MA(y)}=min{MA(y),MA(z)},B~A(x)rmin{B~A(xy),B~A(y)}=rmin{B~A(y),B~A(z)},

and

JA(x)max{JA(xy),JA(y)}=max{JA(y),JA(z)}.

This completes the proof.□

Theorem 3.4

Every MBJ-neutrosophic set in a BCK/BCI-algebra X satisfying (3.1) and (3.4) is an MBJ-neutrosophic ideal of X.

Proof

Let 𝓐 = (MA, A, JA) be an MBJ-neutrosophic set in X satisfying (3.1) and (3.4). Note that x * (x * y) ≤ y for all x, yX. It follows from (3.4) that

MA(x)min{MA(xy),MA(y)},B~A(x)rmin{B~A(xy),B~A(y)},

and

JA(x)max{JA(xy),JA(y)}.

Therefore 𝓐 = (MA, A, JA) is an MBJ-neutrosophic ideal of X.□

Theorem 3.5

Given an MBJ-neutrosophic set 𝓐 = (MA, A, JA) in a BCK/BCI-algebra X, if (MA, JA) is an intuitionistic fuzzy ideal of X, and BA and BA+ are fuzzy ideals of X, then 𝓐 = (MA, A, JA) is an MBJ-neutrosophic ideal of X.

Proof

It is sufficient to show that A satisfies the condition

(xX)(B~A(0)B~A(x)) (3.5)

and

(x,yX)(B~A(x)rmin{B~A(xy),B~A(y)}). (3.6)

For any x, yX, we get

B~A(0)=[BA(0),BA+(0)][BA(x),BA+(x)]=B~A(x)

and

B~A(x)=[BA(x),BA+(x)][min{BA(xy),BA(y)},min{BA+(xy),BA+(y)}]=rmin{[BA(xy),BA+(xy)],[BA(y),BA+(y)]=rmin{B~A(xy),B~A(y)}.

Therefore 𝓐 = (MA, A, JA) is an MBJ-neutrosophic ideal of X.□

If 𝓐 = (MA, A, JA) is an MBJ-neutrosophic ideal of a BCK/BCI-algebra X, then

BA(x),BA+(x)]=B~A(x)rmin{B~A(xy),B~A(y)}=rmin{[BA(xy),BA+(xy),[BA(y),BA+(y)]}=[min{BA(xy),BA(y)},min{BA+(xy),BA+(y)}

for all x, yX. It follows that BA (x) ≥ min{ BA (x * y), BA (y)} and BA+ (x) ≥ min{ BA+ (x * y), BA+ (y)}. Thus BA and BA+ are fuzzy ideals of X. But (MA, JA) is not an intuitionistic fuzzy ideal of X as seen in Example 3.2. This shows that the converse of Theorem 3.5 is not true.

Given an MBJ-neutrosophic set 𝓐 = (MA, A, JA) in a BCK/BCI-algebra X, we consider the following sets.

U(MA;t):={xXMA(x)t},U(B~A;[δ1,δ2]):={xXB~A(x)[δ1,δ2]},L(JA;s):={xXJA(x)s},

where t, s ∈ [0, 1] and [δ1, δ2] ∈ [I].

Theorem 3.6

An MBJ-neutrosophic set 𝓐 = (MA, A, JA) in a BCK/BCI-algebra X is an MBJ-neutrosophic ideal of X if and only if the non-empty sets U(MA; t), U(A;[δ1, δ2]) and L(JA; s) are ideals of X for all t, s ∈ [0, 1] and [δ1, δ2] ∈ [I].

Proof

Suppose that 𝓐 = (MA, A, JA) is an MBJ-neutrosophic ideal of X. Let t, s ∈ [0, 1] and [δ1, δ2] ∈ [I] be such that U(MA; t), U(A;[δ1, δ2]) and L(JA; s) are non-empty. Obviously, 0 ∈ U(MA; t) ∩ U(A;[δ1, δ2]) ∩ L(JA; s). For any x, y, a, b, u, vX, if x * yU(MA; t), yU(MA; t), a * bU(A;[δ1, δ2]), bU(A;[δ1, δ2]), u * vL(JA; s) and vL(JA; s), then

MA(x)min{MA(xy),MA(y)}min{t,t}=t,B~A(a)rmin{B~A(ab),B~A(b)}rmin{[δ1,δ2],[δ1,δ2]}=[δ1,δ2],JA(u)max{JA(uv),JA(v)}min{s,s}=s,

and so xU(MA; t), aU(A;[δ1, δ2]) and uL(JA; s). Therefore U(MA; t), U(A;[δ1, δ2]) and L(JA; s) are ideals of X.

Conversely, assume that the non-empty sets U(MA; t), U(A;[δ1, δ2]) and L(JA; s) are ideals of X for all t, s ∈ [0, 1] and [δ1, δ2] ∈ [I]. Assume that MA(0) < MA(a), A(0) ≺ A(a) and JA(0) > JA(a) for some aX. Then 0 ∉ U(MA; MA(a)) ∩ U(A; A(a)) ∩ L(JA; JA(a), which is a contradiction. Hence MA(0) ≥ MA(x), A(0) ⪰ A(x) and JA(0) ≤ JA(x) for all xX. If

MA(a0)<min{MA(a0b0),MA(b0)}

for some a0, b0X, then a0 * b0U(MA; t0) and b0U(MA; t0) but a0U(MA; t0) for t0 := min{MA(a0 * b0), MA(b0)}. This is a contradiction, and thus MA(a) ≥ min{MA(a * b), MA(b)} for all a, bX. Similarly, we can show that JA(a) ≤ max{JA(a * b), JA(b)} for all a, bX. Suppose that A(a0) ≺ rmin {A(a0 * b0), A(b0)} for some a0, b0X. Let A(a0 * b0) = [λ1, λ2], A(b0) = [λ3, λ4] and A(a0) = [δ1, δ2]. Then

δ1,δ2]rmin{[λ1,λ2],[λ3,λ4]}=[min{λ1,λ3},min{λ2,λ4}

and so δ1 < min{λ1, λ3} and δ2 < min{λ2, λ4}. Taking

[γ1,γ2]:=12B~A(a0)+rmin{B~A(a0b0),B~A(b0)}

implies that

[γ1,γ2]=12[δ1,δ2]+[min{λ1,λ3},min{λ2,λ4}]=12(δ1+min{λ1,λ3}),12(δ2+min{λ2,λ4}).

It follows that

min{λ1,λ3}>γ1=12(δ1+min{λ1,λ3})>δ1

and

min{λ2,λ4}>γ2=12(δ2+min{λ2,λ4})>δ2.

Hence [min{λ1, λ3}, min{λ2, λ4}] ≻ [γ1, γ2] ≻ [δ1, δ2] = A(a0), and therefore a0U(A; [γ1, γ2]). On the other hand,

B~A(a0b0)=[λ1,λ2][min{λ1,λ3},min{λ2,λ4}][γ1,γ2]

and

B~A(b0)=[λ3,λ4][min{λ1,λ3},min{λ2,λ4}][γ1,γ2],

that is, a0 * b0, b0U(A; [γ1, γ2]). This is a contradiction, and therefore A(x) ⪰ rmin {A(x * y), A(y)} for all x, yX. Consequently 𝓐 = (MA, A, JA) is an MBJ-neutrosophic ideal of X.□

Theorem 3.7

Given an ideal I of a BCK/BCI-algebra X, let 𝓐 = (MA, A, JA) be an MBJ-neutrosophic set in X defined by

MA(x)=t ifxI,0 otherwise,B~A(x)=[γ1,γ2] ifxI,[0,0] otherwise,JA(x)=s ifxI,1 otherwise, (3.7)

where t ∈ (0, 1], s ∈ [0, 1) and γ1, γ2 ∈ (0, 1] with γ1 < γ2. Then 𝓐 = (MA, A, JA) is an MBJ-neutrosophic ideal of X such that U(MA; t) = U(A; [γ1, γ2]) = L(JA; s) = I.

Proof

Let x, yX. If x * yI and yI, then xI and so

MA(x)=t=min{MA(xy),MA(y)},B~A(x)=[γ1,γ2]=rmin{[γ1,γ2],[γ1,γ2]}=rmin{B~A(xy),B~A(y)},JA(x)=s=max{JA(xy),JA(y)}.

If any one of x * y and y is contained in I, say x * yK, then MA(x * y) = t, A(x * y) = [γ1, γ2], JA(x * y) = s, MA(y) = 0, A(y) = [0, 0] and JA(y) = 1. Hence

MA(x)0=min{t,0}=min{MA(xy),MA(y)},B~A(x)[0,0]=rmin{[γ1,γ2],[0,0]}=rmin{B~A(xy),B~A(y)},JA(x)1=max{s,1}=max{JA(xy),JA(y)}.

If x * y, yK, then MA(x * y) = 0 = MA(y), A(x * y) = [0, 0] = A(y) and JA(x * y) = 1 = JA(y). It follows that

MA(x)0=min{0,0}=min{MA(xy),MA(y)},B~A(x)[0,0]=rmin{[0,0],[0,0]}=rmin{B~A(xy),B~A(y)},JA(x)1=max{1,1}=max{JA(xy),JA(y)}.

It is obvious that MA(0) ≥ MA(x), A(0)⪰ A(x) and JA(0) ≤ JA(x) for all xX. Therefore 𝓐 = (MA, A, JA) is an MBJ-neutrosophic ideal of X. Obviously, we have U(MA; t) = U(A; [γ1, γ2]) = L(JA; s) = I.□

Theorem 3.8

For any non-empty subset I of X, let 𝓐 = (MA, A, JA) be an MBJ-neutrosophic set in X which is given in (3.7). If 𝓐 = (MA, A, JA) is an MBJ-neutrosophic ideal of X, then I is an ideal of X.

Proof

Obviously, 0 ∈ I. Let x, yX be such that x * yI and yI. Then MA(x * y) = t = MA(y), A(x * y) = [γ1, γ2] = A(y) and JA(x * y) = s = JA(y). Thus

MA(x)min{MA(xy),MA(y)}=t,B~A(x)rmin{B~A(xy),B~A(y)}=[γ1,γ2],JA(x)max{JA(xy),JA(y)}=s,

and hence xI. Therefore I is an ideal of X.□

Theorem 3.9

In a BCK-algebra, every MBJ-neutrosophic ideal is an MBJ-neutrosophic subalgebra.

Proof

Let 𝓐 = (MA, A, JA) be an MBJ-neutrosophic ideal of a BCK-algebra X. Since (x * y) * xy for all x, yX, it follows from Proposition 3.3 that

MA(xy)min{MA(x),MA(y)},B~A(xy)rmin{B~A(x),B~A(y)},JA(xy)max{JA(x),JA(y)}

for all x, yX. Hence 𝓐 = (MA, A, JA) is an MBJ-neutrosophic subalgebra of a BCK-algebra X.□

The converse of Theorem 3.9 may not be true as seen in the following example.

Example 3.10

Consider a BCK-algebra X = {0, 1, 2, 3} with the binary operation * which is given in Table 3. Let 𝓐 = (MA, A, JA) be an MBJ-neutrosophic set in X defined by Table 4. Then 𝓐 = (MA, A, JA) is an MBJ-neutrosophic subalgebra of X, but it is not an MBJ-neutrosophic ideal of X since

Table 3

Cayley table for the binary operation “*”.

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

Table 4

MBJ-neutrosophic set 𝓐 = (MA, A, JA).

X MA(x) A(x) JA(x)
0 0.7 [0.3, 0.8] 0.2
1 0.4 [0.2, 0.6] 0.3
2 0.4 [0.3, 0.8] 0.4
3 0.6 [0.2, 0.6] 0.5

B~A(1)rmin{B~A(12),B~A(2)}.

We provide a condition for an MBJ-neutrosophic subalgebra to be an MBJ-neutrosophic ideal in a BCK-algebra.

Theorem 3.11

Let 𝓐 = (MA, A, JA) be an MBJ-neutrosophic subalgebra of a BCK-algebra X satisfying the condition (3.4). Then 𝓐 = (MA, A, JA) is an MBJ-neutrosophic ideal of X.

Proof

For any xX, we get

MA(0)=MA(xx)min{MA(x),MA(x)}=MA(x),
B~A(0)=B~A(xx)rmin{B~A(x),B~A(x)}=rmin{[BA(x),BA+(x)],[BA(x),BA+(x)]}=[BA(x),BA+(x)]=B~A(x),

and

JA(0)=JA(xx)max{JA(x),JA(x)}=JA(x).

Since x * (x * y) ≤ y for all x, yX, it follows from (3.4) that

MA(x)min{MA(xy),MA(y)},B~A(x)rmin{B~A(xy),B~A(y)},JA(x)max{JA(xy),JA(y)}

for all x, yX. Therefore 𝓐 = (MA, A, JA) is an MBJ-neutrosophic ideal of X.□

Theorem 3.9 is not true in a BCI-algebra as seen in the following example.

Example 3.12

Let (Y, *, 0) be a BCI-algebra and let (ℤ, –, 0) be an adjoint BCI-algebra of the additive group (ℤ, +, 0) of integers. Then X = Y × ℤ is a BCI-algebra and I = Y × ℕ is an ideal of X where ℕ is the set of all non-negative integers (see [17]). Let 𝓐 = (MA, A, JA) be an MBJ-neutrosophic set in X defined by

MA(x)=t ifxI,0 otherwise,B~A(x)=[γ1,γ2]ifxI,[0,0]otherwise,JA(x)=sifxI,1otherwise, (3.8)

where t ∈ (0, 1], s ∈ [0, 1) and γ1, γ2 ∈ (0, 1] with γ1 < γ2. Then 𝓐 = (MA, A, JA) is an MBJ-neutrosophic ideal of X by Theorem 3.7. But it is not an MBJ-neutrosophic subalgebra of X since

MA((0,0)(0,1))=MA((0,1))=0<t=min{MA((0,0)),MA(0,1))},B~A((0,0)(0,2))=B~A((0,2))=[0,0][γ1,γ2]=rmin{B~A((0,0)),B~A(0,2))},

and/or

JA((0,0)(0,3))=JA((0,3))=1>s=max{JA((0,0)),JA(0,3))}.

Definition 3.13

An MBJ-neutrosophic ideal 𝓐 = (MA, A, JA) of a BCI-algebra X is said to be closed if

(xX)(MA(0x)MA(x),B~A(0x)B~A(x),JA(0x)JA(x)). (3.9)

Theorem 3.14

In a BCI-algebra, every closed MBJ-neutrosophic ideal is an MBJ-neutrosophic subalgebra.

Proof

Let 𝓐 = (MA, A, JA) be a closed MBJ-neutrosophic ideal of a BCI-algebra X. Using (3.2), (2.3), (III) and (3.3), we have

MA(xy)min{MA((xy)x),MA(x)}=min{MA(0y),MA(x)}min{MA(y),MA(x)},
B~A(xy)rmin{B~A((xy)x),B~A(x)}=rmin{B~A(0y),B~A(x)}rmin{B~A(y),B~A(x)},

and

JA(xy)max{JA((xy)x),JA(x)}=max{JA(0y),JA(x)}max{JA(y),JA(x)}

for all x, yX. Hence 𝓐 = (MA, A, JA) is an MBJ-neutrosophic subalgebra of X.□

Theorem 3.15

In a weakly BCK-algebra, every MBJ-neutrosophic ideal is closed.

Proof

Let 𝓐 = (MA, A, JA) be an MBJ-neutrosophic ideal of a weakly BCK-algebra X. For any xX, we obtain

MA(0x)min{MA((0x)x),MA(x)}=min{MA(0),MA(x)}=MA(x),B~A(0x)rmin{B~A((0x)x),B~A(x)}=rmin{B~A(0),B~A(x)}=B~A(x),

and

JA(0x)max{JA((0x)x),JA(x)}=max{JA(0),JA(x)}=JA(x).

Therefore 𝓐 = (MA, A, JA) is a closed MBJ-neutrosophic ideal of X.□

Corollary 3.16

In a weakly BCK-algebra, every MBJ-neutrosophic ideal is an MBJ-neutrosophic subalgebra.

The following example shows that any MBJ-neutrosophic subalgebra is not an MBJ-neutrosophic ideal in a BCI-algebra.

Example 3.17

Consider a BCI-algebra X = {0, a, b, c, d, e} with the *-operation in Table 5. Let 𝓐 = (MA, A, JA) be an MBJ-neutrosophic set in X defined by Table 6. It is routine to verify that 𝓐 = (MA, A, JA) is an MBJ-neutrosophic subalgebra of X. But it is not an MBJ-neutrosophic ideal of X since

Table 5

Cayley table for the binary operation “*”.

* 0 a b c d e
0 0 0 c b c c
a a 0 c b c c
b b b 0 c 0 0
c c c b 0 b b
d d b a c 0 a
e e b a c a 0

Table 6

MBJ-neutrosophic set 𝓐 = (MA, A, JA).

X MA(x) A(x) JA(x)
0 0.7 [0.4, 0.9] 0.3
a 0.4 [0.04, 0.45] 0.6
b 0.7 [0.4, 0.9] 0.3
c 0.7 [0.4, 0.9] 0.3
d 0.4 [0.04, 0.45] 0.6
e 0.4 [0.04, 0.45] 0.6

MA(d)<min{MA(dc),MA(c)},B~A(d)rmin{B~A(dc),B~A(c)},

and/or

JA(d)>max{JA(dc),JA(c)}.

Theorem 3.18

In a p-semisimple BCI-algebra X, the following are equivalent.

  1. 𝓐 = (MA, A, JA) is a closed MBJ-neutrosophic ideal of X.

  2. 𝓐 = (MA, A, JA) is an MBJ-neutrosophic subalgebra of X.

Proof

(1) ⇒ (2). See Theorem 3.14.

(2) ⇒ (1). Suppose that 𝓐 = (MA, A, JA) is an MBJ-neutrosophic subalgebra of X. For any xX, we get

MA(0)=MA(xx)min{MA(x),MA(x)}=MA(x),B~A(0)=B~A(xx)rmin{B~A(x),B~A(x)}=B~A(x),

and

JA(0)=JA(xx)max{JA(x),JA(x)}=JA(x).

Hence MA(0 * x) ≥ min{MA(0), MA(x)} = MA(x), A(0 * x) ⪰ rmin{A(0), A(x)} = A(x) and JA(0 * x) ≤ max{JA(0), JA(x)} = JA(x) for all xX. Let x, yX. Then

MA(x)=MA(y(yx))min{MA(y),MA(yx)}=min{MA(y),MA(0(xy))}min{MA(xy),MA(y)},
B~A(x)=B~A(y(yx))rmin{B~A(y),B~A(yx)}=rmin{B~A(y),B~A(0(xy))}rmin{B~A(xy),B~A(y)}

and

JA(x)=JA(y(yx))max{JA(y),JA(yx)}=max{JA(y),JA(0(xy))}max{JA(xy),JA(y)}.

Therefore 𝓐 = (MA, A, JA) is a closed MBJ-neutrosophic ideal of X.□

Since every associative BCI-algebra is p-semisimple, we have the following corollary.

Corollary 3.19

In an associative BCI-algebra X, the following are equivalent.

  1. 𝓐 = (MA, A, JA) is a closed MBJ-neutrosophic ideal of X.

  2. 𝓐 = (MA, A, JA) is an MBJ-neutrosophic subalgebra of X.

Corollary 3.20

In a BCI-algebra X, consider the following conditions

  1. every element x in X is minimal.

  2. X = {0 * x | xX}.

  3. (∀x, yX) (x * (0 * y) = y * (0 * x)).

  4. (∀xX) (0 * x = 0 ⇒ x = 0).

  5. (∀a, xX) (a * (a * x) = x).

  6. (∀aX) X = {a * x | xX}.

  7. (∀x, y, a, bX) ((x * y) * (a * b) = (x * a) * (y * b)).

  8. (∀x, yX) (0 * (y * x) = x * y).

If one of the conditions above is valid, then the following are equivalent.

  1. 𝓐 = (MA, A, JA) is a closed MBJ-neutrosophic ideal of X.

  2. 𝓐 = (MA, A, JA) is an MBJ-neutrosophic subalgebra of X.

Definition 3.21

Let X be an (S)-BCK-algebra. An MBJ-neutrosophic set 𝓐 = (MA, A, JA) in X is called an MBJ-neutrosophic ∘-subalgebra of X if the following assertions are valid.

MA(xy)min{MA(x),MA(y)},B~A(xy)rmin{B~A(x),B~A(y)},JA(xy)max{JA(x),JA(y)} (3.10)

for all x, yX.

Lemma 3.22

Every MBJ-neutrosophic ideal of a BCK/BCI-algebra X satisfies the following assertion.

(x,yX)xyMA(x)MA(y),B~A(x)B~A(y),JA(x)JA(y). (3.11)

Proof

Assume that xy for all x, yX. Then x * y = 0, and so

MA(x)min{MA(xy),MA(y)}=min{MA(0),MA(y)}=MA(y),B~A(x)rmin{B~A(xy),B~A(y)}=rmin{B~A(0),B~A(y)}=B~A(y),

and

JA(x)max{JA(xy),JA(y)}=max{JA(0),JA(y)}=JA(y).

This completes the proof.□

Theorem 3.23

In an (S)-BCK-algebra, every MBJ-neutrosophic ideal is an MBJ-neutrosophic ∘-subalgebra.

Proof

Let 𝓐 = (MA, A, JA) be an MBJ-neutrosophic ideal of an (S)-BCK-algebra X. Note that (xy) * xy for all x, yX. Using Lemma 3.22 and (3.2) implies that

MA(xy)min{MA((xy)x),MA(x)}min{MA(y),MA(x)},B~A(xy)rmin{B~A((xy)x),B~A(x)}rmin{B~A(y),B~A(x)},

and

JA(xy)max{JA((xy)x),JA(x)}max{JA(y),JA(x)}.

Therefore 𝓐 = (MA, A, JA) is an MBJ-neutrosophic ∘$-subalgebra of X.□

We provide a characterization of an MBJ-neutrosophic ideal in an (S)-BCK-algebra.

Theorem 3.24

Let 𝓐 = (MA, A, JA) be an MBJ-neutrosophic set in an (S)-BCK-algebra X. Then 𝓐 = (MA, A, JA) is an MBJ-neutrosophic ideal of X if and only if the following assertions are valid.

MA(x)min{MA(y),MA(z)},B~A(x)rmin{B~A(y),B~A(z)},JA(x)max{JA(y),JA(z)} (3.12)

for all x, y, zX with xyz.

Proof

Assume that 𝓐 = (MA, A, JA) is an MBJ-neutrosophic ideal of X and let x, y, zX be such that xyz. Using (3.1), (3.2) and Theorem 3.23, we have

MA(x)min{MA(x(yz)),MA(yz)}=min{MA(0),MA(yz)}=MA(yz)min{MA(y),MA(z)},
B~A(x)rmin{B~A(x(yz)),B~A(yz)}=rmin{B~A(0),B~A(yz)}=B~A(yz)rmin{B~A(y),B~A(z)},

and

JA(x)max{JA(x(yz)),JA(yz)}=max{JA(0),JA(yz)}=JA(yz)max{JA(y),JA(z)}.

Conversely, let 𝓐 = (MA, A, JA) be an MBJ-neutrosophic set in an (S)-BCK-algebra X satisfying the condition (3.12) for all x, y, zX with xyz. Sine 0 ≤ xx for all xX, it follows from (3.12) that

MA(0)min{MA(x),MA(x)}=MA(x),B~A(0)rmin{B~A(x),B~A(x)}=B~A(x),

and

JA(0)max{JA(x),JA(x)}=JA(x).

Note that x ≤ (x * y) ∘ y for all x, yX. Hence we have

MA(x)min{MA(xy),MA(y)},B~A(x)min{B~A(xy),B~A(y)}andJA(x)max{JA(xy),JA(y)}.

Therefore 𝓐 = (MA, A, JA) is an MBJ-neutrosophic ideal of X.□

References

[1] Zadeh L.A., Fuzzy sets, Information and Control, 1965, 8(3), 338–353.10.21236/AD0608981Search in Google Scholar

[2] Smarandache F., Neutrosophy, Neutrosophic Probability, Set, and Logic, ProQuest Information & Learning, Ann Arbor, Michigan, USA, 1998.Search in Google Scholar

[3] Smarandache F., A unifying field in logics, Neutrosophy: Neutrosophic probability, set and logic, Rehoboth: American Research Press, 1999.Search in Google Scholar

[4] Smarandache F., Neutrosophic set, a generalization of intuitionistic fuzzy sets, International Journal of Pure and Applied Mathematics, 2005, 24(5), 287–297.10.1109/GRC.2006.1635754Search in Google Scholar

[5] Borzooei R.A., Mohseni Takallo M., Smarandache F., Jun Y.B., Positive implicative neutrosophic ideals in BCK-algebras, Neutrosophic Sets and Systems, 2018, 23, 126–141.10.1142/S1793005721500216Search in Google Scholar

[6] Borzooei R.A., Zhan X.H., Smarandache F., Jun Y.B., Commutative generalized neutrosophic ideals in BCK-algebras, Symmetry, 2018, 10, 350, 10.3390/sym10080350.Search in Google Scholar

[7] Jun Y.B., Neutrosophic subalgebras of several types in BCK/BCI-algebras, Ann. Fuzzy Math. Inform., 2017, 14(1), 75–86.10.30948/afmi.2017.14.1.75Search in Google Scholar

[8] Jun Y.B., Kim S.J., Smarandache F., Interval neutrosophic sets with applications in BCK/BCI-algebra, Axioms, 2018, 7, 23.10.3390/axioms7020023Search in Google Scholar

[9] Jun Y.B., Smarandache F., Bordbar H., Neutrosophic ℕ-structures applied to BCK/BCI-algebras, Information, 2017, 8, 128.10.3390/info8040128Search in Google Scholar

[10] Jun Y.B., Smarandache F., Song S.Z., Khan M., Neutrosophic positive implicative ℕ-ideals in BCK/BCI-algebras, Axioms, 2018, 7, 3.10.3390/axioms7010003Search in Google Scholar

[11] Khan M., Anis S., Smarandache F., Jun Y.B., Neutrosophic ℕ-structures and their applications in semigroups, Ann. Fuzzy Math. Inform., 2017, 14(6), 583–598.10.30948/afmi.2017.14.6.583Search in Google Scholar

[12] Öztürk M.A., Jun Y.B., Neutrosophic ideals in BCK/BCI-algebras based on neutrosophic points, J. Inter. Math. Virtual Inst., 2018, 8, 1–17.10.1515/math-2019-0106Search in Google Scholar

[13] Saeid A.B., Jun Y.B., Neutrosophic subalgebras of BCK/BCI-algebras based on neutrosophic points, Ann. Fuzzy Math. Inform., 2017, 14(1), 87–97.10.30948/afmi.2017.14.1.87Search in Google Scholar

[14] Song S.Z., Khan M., Smarandache F., Jun Y.B., A novel extension of neutrosophic sets and Fs application in BCK/BI-algebras, New Trends in Neutrosophic Theory and Applications (Volume II), Pons Editions, Brussels, Belium, EU 2018, 308–326.Search in Google Scholar

[15] Song S.Z., Smarandache F., Jun Y.B., Neutrosophic commutative ℕ-ideals in BCK-algebras, Information, 2017, 8, 130.10.3390/info8040130Search in Google Scholar

[16] Mohseni Takallo M., Borzooei R.A., Jun Y.B., MBJ-neutrosophic structures and its applications in BCK/BCI-algebras, Neutrosophic Sets and Systems, 2018, 23, 72–84.10.3390/axioms7020023Search in Google Scholar

[17] Huang Y.S., BCI-algebra, Beijing: Science Press, 2006.Search in Google Scholar

[18] Meng J., Jun Y.B., BCK-algebras, Kyung Moon Sa Co., Seoul, 1994.Search in Google Scholar
Received: 2018-09-06
Accepted: 2019-02-19
Published Online: 2019-11-28

© 2019 Jun and Roh, published by De Gruyter

This work is licensed under the Creative Commons Attribution 4.0 Public License.

Articles in the same Issue

  1. Regular Articles
  2. On the Gevrey ultradifferentiability of weak solutions of an abstract evolution equation with a scalar type spectral operator of orders less than one
  3. Centralizers of automorphisms permuting free generators
  4. Extreme points and support points of conformal mappings
  5. Arithmetical properties of double Möbius-Bernoulli numbers
  6. The product of quasi-ideal refined generalised quasi-adequate transversals
  7. Characterizations of the Solution Sets of Generalized Convex Fuzzy Optimization Problem
  8. Augmented, free and tensor generalized digroups
  9. Time-dependent attractor of wave equations with nonlinear damping and linear memory
  10. A new smoothing method for solving nonlinear complementarity problems
  11. Almost periodic solution of a discrete competitive system with delays and feedback controls
  12. On a problem of Hasse and Ramachandra
  13. Hopf bifurcation and stability in a Beddington-DeAngelis predator-prey model with stage structure for predator and time delay incorporating prey refuge
  14. A note on the formulas for the Drazin inverse of the sum of two matrices
  15. Completeness theorem for probability models with finitely many valued measure
  16. Periodic solution for ϕ-Laplacian neutral differential equation
  17. Asymptotic orbital shadowing property for diffeomorphisms
  18. Modular equations of a continued fraction of order six
  19. Solutions with concentration and cavitation to the Riemann problem for the isentropic relativistic Euler system for the extended Chaplygin gas
  20. Stability Problems and Analytical Integration for the Clebsch’s System
  21. Topological Indices of Para-line Graphs of V-Phenylenic Nanostructures
  22. On split Lie color triple systems
  23. Triangular Surface Patch Based on Bivariate Meyer-König-Zeller Operator
  24. Generators for maximal subgroups of Conway group Co1
  25. Positivity preserving operator splitting nonstandard finite difference methods for SEIR reaction diffusion model
  26. Characterizations of Convex spaces and Anti-matroids via Derived Operators
  27. On Partitions and Arf Semigroups
  28. Arithmetic properties for Andrews’ (48,6)- and (48,18)-singular overpartitions
  29. A concise proof to the spectral and nuclear norm bounds through tensor partitions
  30. A categorical approach to abstract convex spaces and interval spaces
  31. Dynamics of two-species delayed competitive stage-structured model described by differential-difference equations
  32. Parity results for broken 11-diamond partitions
  33. A new fourth power mean of two-term exponential sums
  34. The new operations on complete ideals
  35. Soft covering based rough graphs and corresponding decision making
  36. Complete convergence for arrays of ratios of order statistics
  37. Sufficient and necessary conditions of convergence for ρ͠ mixing random variables
  38. Attractors of dynamical systems in locally compact spaces
  39. Random attractors for stochastic retarded strongly damped wave equations with additive noise on bounded domains
  40. Statistical approximation properties of λ-Bernstein operators based on q-integers
  41. An investigation of fractional Bagley-Torvik equation
  42. Pentavalent arc-transitive Cayley graphs on Frobenius groups with soluble vertex stabilizer
  43. On the hybrid power mean of two kind different trigonometric sums
  44. Embedding of Supplementary Results in Strong EMT Valuations and Strength
  45. On Diophantine approximation by unlike powers of primes
  46. A General Version of the Nullstellensatz for Arbitrary Fields
  47. A new representation of α-openness, α-continuity, α-irresoluteness, and α-compactness in L-fuzzy pretopological spaces
  48. Random Polygons and Estimations of π
  49. The optimal pebbling of spindle graphs
  50. MBJ-neutrosophic ideals of BCK/BCI-algebras
  51. A note on the structure of a finite group G having a subgroup H maximal in 〈H, Hg
  52. A fuzzy multi-objective linear programming with interval-typed triangular fuzzy numbers
  53. Variational-like inequalities for n-dimensional fuzzy-vector-valued functions and fuzzy optimization
  54. Stability property of the prey free equilibrium point
  55. Rayleigh-Ritz Majorization Error Bounds for the Linear Response Eigenvalue Problem
  56. Hyper-Wiener indices of polyphenyl chains and polyphenyl spiders
  57. Razumikhin-type theorem on time-changed stochastic functional differential equations with Markovian switching
  58. Fixed Points of Meromorphic Functions and Their Higher Order Differences and Shifts
  59. Properties and Inference for a New Class of Generalized Rayleigh Distributions with an Application
  60. Nonfragile observer-based guaranteed cost finite-time control of discrete-time positive impulsive switched systems
  61. Empirical likelihood confidence regions of the parameters in a partially single-index varying-coefficient model
  62. Algebraic loop structures on algebra comultiplications
  63. Two weight estimates for a class of (p, q) type sublinear operators and their commutators
  64. Dynamic of a nonautonomous two-species impulsive competitive system with infinite delays
  65. 2-closures of primitive permutation groups of holomorph type
  66. Monotonicity properties and inequalities related to generalized Grötzsch ring functions
  67. Variation inequalities related to Schrödinger operators on weighted Morrey spaces
  68. Research on cooperation strategy between government and green supply chain based on differential game
  69. Extinction of a two species competitive stage-structured system with the effect of toxic substance and harvesting
  70. *-Ricci soliton on (κ, μ)′-almost Kenmotsu manifolds
  71. Some improved bounds on two energy-like invariants of some derived graphs
  72. Pricing under dynamic risk measures
  73. Finite groups with star-free noncyclic graphs
  74. A degree approach to relationship among fuzzy convex structures, fuzzy closure systems and fuzzy Alexandrov topologies
  75. S-shaped connected component of radial positive solutions for a prescribed mean curvature problem in an annular domain
  76. On Diophantine equations involving Lucas sequences
  77. A new way to represent functions as series
  78. Stability and Hopf bifurcation periodic orbits in delay coupled Lotka-Volterra ring system
  79. Some remarks on a pair of seemingly unrelated regression models
  80. Lyapunov stable homoclinic classes for smooth vector fields
  81. Stabilizers in EQ-algebras
  82. The properties of solutions for several types of Painlevé equations concerning fixed-points, zeros and poles
  83. Spectrum perturbations of compact operators in a Banach space
  84. The non-commuting graph of a non-central hypergroup
  85. Lie symmetry analysis and conservation law for the equation arising from higher order Broer-Kaup equation
  86. Positive solutions of the discrete Dirichlet problem involving the mean curvature operator
  87. Dislocated quasi cone b-metric space over Banach algebra and contraction principles with application to functional equations
  88. On the Gevrey ultradifferentiability of weak solutions of an abstract evolution equation with a scalar type spectral operator on the open semi-axis
  89. Differential polynomials of L-functions with truncated shared values
  90. Exclusion sets in the S-type eigenvalue localization sets for tensors
  91. Continuous linear operators on Orlicz-Bochner spaces
  92. Non-trivial solutions for Schrödinger-Poisson systems involving critical nonlocal term and potential vanishing at infinity
  93. Characterizations of Benson proper efficiency of set-valued optimization in real linear spaces
  94. A quantitative obstruction to collapsing surfaces
  95. Dynamic behaviors of a Lotka-Volterra type predator-prey system with Allee effect on the predator species and density dependent birth rate on the prey species
  96. Coexistence for a kind of stochastic three-species competitive models
  97. Algebraic and qualitative remarks about the family yy′ = (αxm+k–1 + βxmk–1)y + γx2m–2k–1
  98. On the two-term exponential sums and character sums of polynomials
  99. F-biharmonic maps into general Riemannian manifolds
  100. Embeddings of harmonic mixed norm spaces on smoothly bounded domains in ℝn
  101. Asymptotic behavior for non-autonomous stochastic plate equation on unbounded domains
  102. Power graphs and exchange property for resolving sets
  103. On nearly Hurewicz spaces
  104. Least eigenvalue of the connected graphs whose complements are cacti
  105. Determinants of two kinds of matrices whose elements involve sine functions
  106. A characterization of translational hulls of a strongly right type B semigroup
  107. Common fixed point results for two families of multivalued A–dominated contractive mappings on closed ball with applications
  108. Lp estimates for maximal functions along surfaces of revolution on product spaces
  109. Path-induced closure operators on graphs for defining digital Jordan surfaces
  110. Irreducible modules with highest weight vectors over modular Witt and special Lie superalgebras
  111. Existence of periodic solutions with prescribed minimal period of a 2nth-order discrete system
  112. Injective hulls of many-sorted ordered algebras
  113. Random uniform exponential attractor for stochastic non-autonomous reaction-diffusion equation with multiplicative noise in ℝ3
  114. Global properties of virus dynamics with B-cell impairment
  115. The monotonicity of ratios involving arc tangent function with applications
  116. A family of Cantorvals
  117. An asymptotic property of branching-type overloaded polling networks
  118. Almost periodic solutions of a commensalism system with Michaelis-Menten type harvesting on time scales
  119. Explicit order 3/2 Runge-Kutta method for numerical solutions of stochastic differential equations by using Itô-Taylor expansion
  120. L-fuzzy ideals and L-fuzzy subalgebras of Novikov algebras
  121. L-topological-convex spaces generated by L-convex bases
  122. An optimal fourth-order family of modified Cauchy methods for finding solutions of nonlinear equations and their dynamical behavior
  123. New error bounds for linear complementarity problems of Σ-SDD matrices and SB-matrices
  124. Hankel determinant of order three for familiar subsets of analytic functions related with sine function
  125. On some automorphic properties of Galois traces of class invariants from generalized Weber functions of level 5
  126. Results on existence for generalized nD Navier-Stokes equations
  127. Regular Banach space net and abstract-valued Orlicz space of range-varying type
  128. Some properties of pre-quasi operator ideal of type generalized Cesáro sequence space defined by weighted means
  129. On a new convergence in topological spaces
  130. On a fixed point theorem with application to functional equations
  131. Coupled system of a fractional order differential equations with weighted initial conditions
  132. Rough quotient in topological rough sets
  133. Split Hausdorff internal topologies on posets
  134. A preconditioned AOR iterative scheme for systems of linear equations with L-matrics
  135. New handy and accurate approximation for the Gaussian integrals with applications to science and engineering
  136. Special Issue on Graph Theory (GWGT 2019)
  137. The general position problem and strong resolving graphs
  138. Connected domination game played on Cartesian products
  139. On minimum algebraic connectivity of graphs whose complements are bicyclic
  140. A novel method to construct NSSD molecular graphs
https://doi.org/10.1515/math-2019-0106
Keywords for this article
MBJ-neutrosophic set; MBJ-neutrosophic subalgebra; MBJ-neutrosophic ideal; MBJ-neutro-sophic ∘-subalgebra
Creative Commons
BY 4.0

Articles in the same Issue

  1. Regular Articles
  2. On the Gevrey ultradifferentiability of weak solutions of an abstract evolution equation with a scalar type spectral operator of orders less than one
  3. Centralizers of automorphisms permuting free generators
  4. Extreme points and support points of conformal mappings
  5. Arithmetical properties of double Möbius-Bernoulli numbers
  6. The product of quasi-ideal refined generalised quasi-adequate transversals
  7. Characterizations of the Solution Sets of Generalized Convex Fuzzy Optimization Problem
  8. Augmented, free and tensor generalized digroups
  9. Time-dependent attractor of wave equations with nonlinear damping and linear memory
  10. A new smoothing method for solving nonlinear complementarity problems
  11. Almost periodic solution of a discrete competitive system with delays and feedback controls
  12. On a problem of Hasse and Ramachandra
  13. Hopf bifurcation and stability in a Beddington-DeAngelis predator-prey model with stage structure for predator and time delay incorporating prey refuge
  14. A note on the formulas for the Drazin inverse of the sum of two matrices
  15. Completeness theorem for probability models with finitely many valued measure
  16. Periodic solution for ϕ-Laplacian neutral differential equation
  17. Asymptotic orbital shadowing property for diffeomorphisms
  18. Modular equations of a continued fraction of order six
  19. Solutions with concentration and cavitation to the Riemann problem for the isentropic relativistic Euler system for the extended Chaplygin gas
  20. Stability Problems and Analytical Integration for the Clebsch’s System
  21. Topological Indices of Para-line Graphs of V-Phenylenic Nanostructures
  22. On split Lie color triple systems
  23. Triangular Surface Patch Based on Bivariate Meyer-König-Zeller Operator
  24. Generators for maximal subgroups of Conway group Co1
  25. Positivity preserving operator splitting nonstandard finite difference methods for SEIR reaction diffusion model
  26. Characterizations of Convex spaces and Anti-matroids via Derived Operators
  27. On Partitions and Arf Semigroups
  28. Arithmetic properties for Andrews’ (48,6)- and (48,18)-singular overpartitions
  29. A concise proof to the spectral and nuclear norm bounds through tensor partitions
  30. A categorical approach to abstract convex spaces and interval spaces
  31. Dynamics of two-species delayed competitive stage-structured model described by differential-difference equations
  32. Parity results for broken 11-diamond partitions
  33. A new fourth power mean of two-term exponential sums
  34. The new operations on complete ideals
  35. Soft covering based rough graphs and corresponding decision making
  36. Complete convergence for arrays of ratios of order statistics
  37. Sufficient and necessary conditions of convergence for ρ͠ mixing random variables
  38. Attractors of dynamical systems in locally compact spaces
  39. Random attractors for stochastic retarded strongly damped wave equations with additive noise on bounded domains
  40. Statistical approximation properties of λ-Bernstein operators based on q-integers
  41. An investigation of fractional Bagley-Torvik equation
  42. Pentavalent arc-transitive Cayley graphs on Frobenius groups with soluble vertex stabilizer
  43. On the hybrid power mean of two kind different trigonometric sums
  44. Embedding of Supplementary Results in Strong EMT Valuations and Strength
  45. On Diophantine approximation by unlike powers of primes
  46. A General Version of the Nullstellensatz for Arbitrary Fields
  47. A new representation of α-openness, α-continuity, α-irresoluteness, and α-compactness in L-fuzzy pretopological spaces
  48. Random Polygons and Estimations of π
  49. The optimal pebbling of spindle graphs
  50. MBJ-neutrosophic ideals of BCK/BCI-algebras
  51. A note on the structure of a finite group G having a subgroup H maximal in 〈H, Hg
  52. A fuzzy multi-objective linear programming with interval-typed triangular fuzzy numbers
  53. Variational-like inequalities for n-dimensional fuzzy-vector-valued functions and fuzzy optimization
  54. Stability property of the prey free equilibrium point
  55. Rayleigh-Ritz Majorization Error Bounds for the Linear Response Eigenvalue Problem
  56. Hyper-Wiener indices of polyphenyl chains and polyphenyl spiders
  57. Razumikhin-type theorem on time-changed stochastic functional differential equations with Markovian switching
  58. Fixed Points of Meromorphic Functions and Their Higher Order Differences and Shifts
  59. Properties and Inference for a New Class of Generalized Rayleigh Distributions with an Application
  60. Nonfragile observer-based guaranteed cost finite-time control of discrete-time positive impulsive switched systems
  61. Empirical likelihood confidence regions of the parameters in a partially single-index varying-coefficient model
  62. Algebraic loop structures on algebra comultiplications
  63. Two weight estimates for a class of (p, q) type sublinear operators and their commutators
  64. Dynamic of a nonautonomous two-species impulsive competitive system with infinite delays
  65. 2-closures of primitive permutation groups of holomorph type
  66. Monotonicity properties and inequalities related to generalized Grötzsch ring functions
  67. Variation inequalities related to Schrödinger operators on weighted Morrey spaces
  68. Research on cooperation strategy between government and green supply chain based on differential game
  69. Extinction of a two species competitive stage-structured system with the effect of toxic substance and harvesting
  70. *-Ricci soliton on (κ, μ)′-almost Kenmotsu manifolds
  71. Some improved bounds on two energy-like invariants of some derived graphs
  72. Pricing under dynamic risk measures
  73. Finite groups with star-free noncyclic graphs
  74. A degree approach to relationship among fuzzy convex structures, fuzzy closure systems and fuzzy Alexandrov topologies
  75. S-shaped connected component of radial positive solutions for a prescribed mean curvature problem in an annular domain
  76. On Diophantine equations involving Lucas sequences
  77. A new way to represent functions as series
  78. Stability and Hopf bifurcation periodic orbits in delay coupled Lotka-Volterra ring system
  79. Some remarks on a pair of seemingly unrelated regression models
  80. Lyapunov stable homoclinic classes for smooth vector fields
  81. Stabilizers in EQ-algebras
  82. The properties of solutions for several types of Painlevé equations concerning fixed-points, zeros and poles
  83. Spectrum perturbations of compact operators in a Banach space
  84. The non-commuting graph of a non-central hypergroup
  85. Lie symmetry analysis and conservation law for the equation arising from higher order Broer-Kaup equation
  86. Positive solutions of the discrete Dirichlet problem involving the mean curvature operator
  87. Dislocated quasi cone b-metric space over Banach algebra and contraction principles with application to functional equations
  88. On the Gevrey ultradifferentiability of weak solutions of an abstract evolution equation with a scalar type spectral operator on the open semi-axis
  89. Differential polynomials of L-functions with truncated shared values
  90. Exclusion sets in the S-type eigenvalue localization sets for tensors
  91. Continuous linear operators on Orlicz-Bochner spaces
  92. Non-trivial solutions for Schrödinger-Poisson systems involving critical nonlocal term and potential vanishing at infinity
  93. Characterizations of Benson proper efficiency of set-valued optimization in real linear spaces
  94. A quantitative obstruction to collapsing surfaces
  95. Dynamic behaviors of a Lotka-Volterra type predator-prey system with Allee effect on the predator species and density dependent birth rate on the prey species
  96. Coexistence for a kind of stochastic three-species competitive models
  97. Algebraic and qualitative remarks about the family yy′ = (αxm+k–1 + βxmk–1)y + γx2m–2k–1
  98. On the two-term exponential sums and character sums of polynomials
  99. F-biharmonic maps into general Riemannian manifolds
  100. Embeddings of harmonic mixed norm spaces on smoothly bounded domains in ℝn
  101. Asymptotic behavior for non-autonomous stochastic plate equation on unbounded domains
  102. Power graphs and exchange property for resolving sets
  103. On nearly Hurewicz spaces
  104. Least eigenvalue of the connected graphs whose complements are cacti
  105. Determinants of two kinds of matrices whose elements involve sine functions
  106. A characterization of translational hulls of a strongly right type B semigroup
  107. Common fixed point results for two families of multivalued A–dominated contractive mappings on closed ball with applications
  108. Lp estimates for maximal functions along surfaces of revolution on product spaces
  109. Path-induced closure operators on graphs for defining digital Jordan surfaces
  110. Irreducible modules with highest weight vectors over modular Witt and special Lie superalgebras
  111. Existence of periodic solutions with prescribed minimal period of a 2nth-order discrete system
  112. Injective hulls of many-sorted ordered algebras
  113. Random uniform exponential attractor for stochastic non-autonomous reaction-diffusion equation with multiplicative noise in ℝ3
  114. Global properties of virus dynamics with B-cell impairment
  115. The monotonicity of ratios involving arc tangent function with applications
  116. A family of Cantorvals
  117. An asymptotic property of branching-type overloaded polling networks
  118. Almost periodic solutions of a commensalism system with Michaelis-Menten type harvesting on time scales
  119. Explicit order 3/2 Runge-Kutta method for numerical solutions of stochastic differential equations by using Itô-Taylor expansion
  120. L-fuzzy ideals and L-fuzzy subalgebras of Novikov algebras
  121. L-topological-convex spaces generated by L-convex bases
  122. An optimal fourth-order family of modified Cauchy methods for finding solutions of nonlinear equations and their dynamical behavior
  123. New error bounds for linear complementarity problems of Σ-SDD matrices and SB-matrices
  124. Hankel determinant of order three for familiar subsets of analytic functions related with sine function
  125. On some automorphic properties of Galois traces of class invariants from generalized Weber functions of level 5
  126. Results on existence for generalized nD Navier-Stokes equations
  127. Regular Banach space net and abstract-valued Orlicz space of range-varying type
  128. Some properties of pre-quasi operator ideal of type generalized Cesáro sequence space defined by weighted means
  129. On a new convergence in topological spaces
  130. On a fixed point theorem with application to functional equations
  131. Coupled system of a fractional order differential equations with weighted initial conditions
  132. Rough quotient in topological rough sets
  133. Split Hausdorff internal topologies on posets
  134. A preconditioned AOR iterative scheme for systems of linear equations with L-matrics
  135. New handy and accurate approximation for the Gaussian integrals with applications to science and engineering
  136. Special Issue on Graph Theory (GWGT 2019)
  137. The general position problem and strong resolving graphs
  138. Connected domination game played on Cartesian products
  139. On minimum algebraic connectivity of graphs whose complements are bicyclic
  140. A novel method to construct NSSD molecular graphs
Sign up now to receive a 20% welcome discount
Institutional Access
How does access work?
Have an idea on how to improve our website?
Please write us.
© 2025 De Gruyter Brill
Downloaded on 24.12.2025 from https://www.degruyterbrill.com/document/doi/10.1515/math-2019-0106/html
Scroll to top button