Definition 1. (Kim and Kim [³])

By a BE-algebra we shall mean an algebra (X; *, 1) of type (2,0) satisfying the following axioms:

• •

  (BE1) x * x = 1,

• •

  (BE2) x * 1 = 1,

• •

  (BE3) 1 * x = x,

• •

  (BE4) x * (y * z) = y * (x * z), for all x,y,z ∈ X.

From now on X is a BE-algebra, unless otherwise is stated. We introduce a relation “≤” on X by x ≤ y if and only if x * y = 1. A BE-algebra X is said to be a self distributive if x * (y * z) = (x * y) * (x * z), for all x,y,z ∈ X. A BE-algebra X is said to be commutative if satisfies:

Proposition 1. (Walendziak [¹³])

If X is a commutative BE-algebra, then for all x,y ∈ X,

We note that “≤” is reflexive by (BE1). If X is self distributive then relation “≤” is a transitive ordered set on X, because if x ≤ y and y ≤ z, then

Hence x ≤ z. If X is commutative then by Proposition 1, relation “≤” is antisymmetric. Hence if X is a commutative self distributive BE-algebra, then relation “≤” is a partial ordered set on X.

Proposition 2. (Kim and Kim [³])

In a BE-algebra X, the following holds:

1. (i)

   x * (y * x) = 1,

2. (ii)

   y * ((y * x) * x) = 1, for all x,y ∈ X.

A subset F of X is called a filter of X if it satisfies: (F1) 1 ∈ F, (F2) x ∈ F and x * y ∈ F imply y ∈ F. Define

which is called an upper set of x and y. It is easy to see that 1,x,y ∈ A(x,y), for any x,y ∈ X. Every upper set A(x,y) need not be a filter of X in general.

Definition 2. (Borumand and Rezaei [²])

A nonempty subset F of X is called an implicative filter if satisfies the following conditions:

• (IF1)

  1 ∈ F,

• (IF2)

  x * (y * z) ∈ F and x * y ∈ F imply that x * z ∈ F, for all x,y,z ∈ X.

If we replace x of the condition (IF2) by the element 1, then it can be easily observed that every implicative filter is a filter. However, every filter is not an implicative filter as shown in the following example.

Example 1.

Let X = {1,a,b} be a BE-algebra with the following table:

Then F = {1,a} is a filter of X, but it is not an implicative filter, since 1 * (a * b) = 1 * a = a ∈ F and 1 * a = a ∈ F but 1 * b = b ∉ F.

Definition 3.

Let (X₁; *, 1) and (X₂; ○, 1′)) be two BE-algebras. Then a mapping f : X₁ → X₂ is called a homomorphism if f(x₁ * x₂) = f(x₁) ○ f(x₂), for all x₁,x₂ ∈ X₁. It is clear that if f : X₁ → X₂ is a homomorphism, then f(1) = 1′.

Definition 4. (Rezaei and Borumand [⁶])

A fuzzy set μ of X is called a fuzzy filter if satisfies the following conditions:

• (FF1)

  μ(1) ≥ μ(x),

• (FF2)

  μ(y) ≥ min{μ(x * y), μ(x)}, for all x,y ∈ X.

Definition 5. (Rao [⁹])

A fuzzy set μ of X is called a fuzzy implicative filter of X if satisfies the following conditions:

• (FIF1)

  μ(1) ≥ μ(x),

• (FIF2)

  μ(x * z) ≥ min{μ(x * (y * z)), μ(x * y)}, for all x,y,z ∈ X.

If we replace x of the condition (FIF2) by the element 1, then it can be easily observed that every fuzzy implicative filter is a fuzzy filter. However, every fuzzy filter is not a fuzzy implicative filter as shown in the following example.

Example 2. (Rao [⁹])

Let X = {1,a,b,c,d} be a BE-algebra with the following table:

Then it can be easily verified that (X; *, 1) is a BE-algebra. Define a fuzzy set μ on X as follows:

Then clearly μ is a fuzzy filter of X, but it is not a fuzzy implicative filter of X, since

Definition 6. (Torra [¹⁰])

Let X be a reference set. Then a hesitant fuzzy set HFS A in X is represented mathematical as:

where ρ([0,1]) is the power set of [0,1].

So, we can define a set of fuzzy sets an HFS by union of their membership functions.

Definition 7. (Torra [¹⁰])

Let A = {μ₁,μ₂,…,μ_n} be a set of n membership functions. The HFS that is associated with A, h_A, is defined as

It is remarkable that this definition is quite suitable to decision making, when experts have to assess a set of alternatives. In such a case, A represents the assessments of the experts for each alternative and h_A the assessments of the set of experts. However, note that it only allows to recover those HFSs whose memberships are given by sets of cardinality less than or equal to n.

For convenience, Xia and Xu in [¹⁴] named the set h = h_A(x) as a hesitant fuzzy element HFE. The family of all hesitant fuzzy elements defined on X by HFE(X).

Definition 8. (Verma and Dev Sharma [¹²])

Let h,h₁,h₂ ∈ HFE(X) and λ ∈ [0,1]. Then the operations complement, union and intersection are defined as follows:

1. (i)

   h^c = {1 − γ : γ ∈ h},

2. (ii)

   h₁ ⊔ h₂ = {max(γ₁,γ₂) : γ₁ ∈ h₁,γ₂ ∈ h₂},

3. (iii)

   h₁ ⊓ h₂ = {min(γ₁,γ₂) : γ₁ ∈ h₁,γ₂ ∈ h₂},

4. (iv)

   h₁ ⊕ h₂ = {γ₁ + γ₂ − γ₁γ₂ : γ₁ ∈ h₁,γ₂ ∈ h₂},

5. (v)

   h₁ ⊗ h₂ = {γ₁γ₂ : γ₁ ∈ h₁,γ₂ ∈ h₂},

6. (vi)

   λh = {1 − (1 − γ)^λ : γ ∈ h}.

Definition 9.

Hesitant fuzzy set A of X is called a hesitant fuzzy filter if satisfies the following conditions:

• •

  (HFF1) h_A(x) ⊑ h_A(1),

• •

  (HFF2) h_A(x) ⊓ h_A(x * y) ⊑ h_A(y), for all x,y ∈ X.

Denote the set of all hesitant fuzzy filters of X by HFF(X).

Note. If |h_A(x)| = 1, for all x ∈ X, then h_A is a fuzzy filter. In fact in this case we put “≤≔⊑” and “min ≔ ⊓”.

Example 3.

Let X = {1,a,b} be a BE-algebra with the following table:

Let t₁ = {0.2,0.3}, t₂ = {0.4,0.5} and t₃ = {0.6,0.8}. Define A as h_A(1) = t₃, h_A(a) = t₂ and h_A(b) = t₁. Then A is a hesitant fuzzy filter.

Proposition 3.

Let A ∈ HFF(X) and x,y,z,a_i ∈ X for i = 1,…,n. Then

1. (i)

   if x ≤ y, then h_A(x) ⊑ h_A(y),

2. (ii)

   h_A(x) ⊑ h_A(y * x),

3. (iii)

   h_A(x) ⊓ h_A(y) ⊑ h_A(x * y),

4. (iv)

   h_A(x) ⊑ h_A((x * y) * y),

5. (v)

   h_A(x) ⊓ h_A(y) ⊑ h_A((x * (y * z)) * z),

6. (vi)

   if h_A(y) ⊓ h_A((x * y) * z) ⊑ h_A(z * x), then h_A is antitonic (i.e. if x ≤ y, then h_A(y) ⊑ h_A(x)),

7. (vii)

   if z ∈ A(x,y), then h_A(x) ⊓ h_A(y) ⊑ h_A(z),

8. (viii)

   if ∏i=1nai*x=1 , then ⊓i=1nhA(ai)⊑hA(x) , where

   ∏i=1nai*x=an*(an−1*(…(a1*x)…)).

Proof.

1. (i).

   Let x ≤ y. Then x * y = 1 and so by using (BE2) and Definition 9 (HFF2), we have

   hA(x)=hA(x)⊓hA(1)=hA(x)⊓hA(y*1)⊑hA(y).

2. (ii).

   Since x ≤ (y * x), by using (i) we have h_A(x) ⊑ h_A(y * x).

3. (iii).

   By using (ii) we have

   hA(x)⊓hA(y)⊑hA(y)⊑hA(x*y).

4. (iv).

   It follows from Definition 9,

   hA(x)=hA(x)⊓hA(1)=hA(x)⊓hA((x*y)*(x*y))=hA(x)⊓hA(x*((x*y)*x))⊑hA((x*y)*y).

5. (v).

   From (iv) we have

   hA(x)⊓hA(y)⊑hA((x*(y*x))*(y*x))⊓hA(y)⊑hA((x*(y*z))*z).

6. (vi).

   Let x ≤ y, that is, x * y = 1.

   hA(y)=hA(y)⊓hA(1*1)=hA(y)⊓hA((x*y)*1)⊑hA(1*x)=hA(x).

7. (vii).

   Let z ∈ A(x,y). Then x * (y * z) = 1. Hence

   hA(x)⊓hA(y)=hA(x)⊓hA(y)⊓hA(1)=hA(x)⊓hA(y)⊓hA(x*(y*z))⊑hA(y)⊓hA(y*z)⊑hA(z).

8. (viii).

   The proof is by induction on n. By (vii) it is true for n = 1, 2. Assume that it satisfies for n = k, that is,

   ∏i=1kai*x=1⇒⊓i=1khA(ai)⊑hA(x),

   for all a₁,…,a_k, x ∈ X.

Suppose that ∏i=1k+1ai*x=1 , for all a₁,…,a_k, a_k+1, x ∈ X. Then

Since A is a hesitant fuzzy filter of X, we have

Example 4.

In Example 3, we have hAc(1)={0.4,0.2} , hAc(a)={0.6,0.5} and hAc(b)={0.8,0.7} and so hAc∉HFF(X) because hAc(1)⊏hAc(a) .

Theorem 4.

Let h,h₁,h₂ ∈ HFF(X) and λ ∈ [0,1]. Then

1. (i)

   h₁ ⊔ h₂ ∈ HFF(X),

2. (ii)

   h₁ ⊓ h₂ ∈ HFF(X),

3. (iii)

   h₁ ⊕ h₂ ∈ HFF(X),

4. (iv)

   h₁ ⊗ h₂ ∈ HFF(X),

5. (v)

   λh ∈ HFF(X).

Proof.

1. (i).

   Assume that h₁,h₂ ∈ HFF(X) and x ∈ X. Then

   (h1⊔h2)(x)={max(γ1,γ2) : γ1∈h1(x),γ2∈h2(x)}⊑{max(γ1,γ2) : γ1∈h1(1),γ2∈h2(1)}=(h1⊔h2)(1).

   Now, we have

   (h1⊔h2) (x*y)⊓(h1⊔h2) (x)={max(γ1,γ2) : γ1∈h1(x*y),γ2∈h2(x*y)}⊓{max(η1,η2) : η1∈h1(x),η2∈h2(x)}={max(β1,β2) : β1∈h1(x*y)⊓h1(x),β2∈h2(x*y)⊓h2(x)}⊑{max(β1,β2) : β1∈h1(y),β2∈h2(y)}=(h1⊔h2) (y).

   Therefore, h₁ ⊔ h₂ ∈ HFF(X).

2. (ii).

   Assume that h₁,h₂ ∈ HFF(X) and x ∈ X. Then

   (h1⊓h2) (x)={min(γ1,γ2) : γ1∈h1(x),γ2∈h2(x)}⊑{min(γ1,γ2) : γ1∈h1(1),γ2∈h2(1)}=(h1⊓h2) (1).

   Now, we have

   (h1⊓h2) (x*y)⊓(h1⊓h2) (x)={min(γ1,γ2) : γ1∈h1(x*y),γ2∈h2(x*y)}⊓{min(η1,η2) : η1∈h1(x),η2∈h2(x)}={min(β1,β2) : β1∈h1(x*y)⊓h1(x),β2∈h2(x*y)⊓h2(x)}⊑{min(β1,β2) : β1∈h1(y),β2∈h2(y)}=(h1⊓h2) (y).

   Therefore, h₁ ⊓ h₂ ∈ HFF(X).

3. (iii).

   Assume that h₁,h₂ ∈ HFF(X) and x ∈ X. Then (h₁ ⊕ h₂) (x)

   ={γ1+γ2−γ1γ2 : γ1∈h1(x),γ2∈h2(x)}⊑{γ1+γ2−γ1γ2 : γ1∈h1(1),γ2∈h2(1)}=(h1⊕h2) (1).

   Now, we have

   (h1⊕h2) (x*y)⊓(h1⊕h2) (x)={γ1+γ2−γ1γ2 : γ1∈h1(x*y),γ2∈h2(x*y)}⊓{η1+η2−η1η2 : η1∈h1(x),η2∈h2(x)}={β1+β2−β1β2 : β1∈h1(x*y)⊓h1(x),β2∈h2(x*y)⊓h2(x)}⊑{β1+β2−β1β2 : β1∈h1(y),β2∈h2(y)}=(h1⊕h2) (y).

   Therefore, h₁ ⊕ h₂ ∈ HFF(X).

4. (iv).

   Assume that h₁,h₂ ∈ HFF(X) and x ∈ X. Then

   (h1⊗h2) (x)={γ1γ2 : γ1∈h1(x),γ2∈h2(x)}⊑{γ1γ2 : γ1∈h1(1),γ2∈h2(1)}=(h1⊗h2) (1).

   Now, we have

   (h1⊗h2) (x*y)⊓(h1⊗h2) (x)={γ1γ2 : γ1∈h1(x*y),γ2∈h2(x*y)}⊓{η1η2 : η1∈h1(x),η2∈h2(x)}={β1β2 : β1∈h1(x*y)⊓h1(x),β2∈h2(x*y)⊓h2(x)}⊑{β1β2 : β1∈h1(y),β2∈h2(y)}=(h1⊗h2) (y).

   Therefore, h₁ ⊗ h₂ ∈ HFF(X).

5. (v).

   Assume that h ∈ HFF(X), x ∈ X and λ ∈ [0,1].

   λh(x)={1−(1−γ)λ : γ∈h(x)}⊑{1−(1−γ)λ : γ∈h(1)}=λh(1).

   Now, we have

   λh(x*y)⊓λh(x)={1−(1−γ)λ : γ∈h(x*y)}⊓{1−(1−η)λ : η∈h(x)}={1−(1−β)λ : β∈h(x*y)⊓h(x)}⊑{1−(1−β)λ : β∈h(y)}=λh(y).

   Therefore, λh ∈ HFF(X).

Lemma 5.

If {h_i}_i∈Λ ∈ HFF(X), then ⊓_i∈Λh_i, is too.

Proof.

Straightforward.

Theorem 6.

(HFF(X); ⊑) is a complete lattice, but it is not a Boolean algebra.

Proof.

By Theorem 4 and Lemma 5, the proof is obvious. Example 4 shows that it is not a Boolean algebra.

Theorem 7.

Let A ∈ HFF(X). Then the set

is a filter of X.

Proof.

Obviously, 1 ∈ X_hA. Let x,x * y ∈ X_hA. Then h_A(x) = h_A(x * y) = h_A(1). Now, by Definition 9, we have

Hence h_A(y) = h_A(1). Therefore, y ∈ X_hA.

Example 5.

In Example 3, γ ≔ {0.1,0.4}, we have i_A(h_A;γ) = {1,a}.

Theorem 8.

Let A ∈ HFS(X). The following are equivalent:

1. (i)

   A ∈ HFF(X),

2. (ii)

   (∀γ ∈ ρ([0,1])) i_A(h_A;γ) ≠ ∅ imply i_A(h_A;γ) is a filter of X.

Proof.

• (i) ⇒ (ii). Let x,y ∈ X be such that x,x * y ∈ i_A(h_A;γ), for any γ ∈ ρ([0,1]).

  Then γ ⊑ h_A(x) and γ ⊑ h_A(x * y). Hence

  γ⊑hA(x)⊓hA(x*y)⊑hA(y).

  Since h_A is a hesitant fuzzy filter, we have y ∈ i_A(h_A;γ).

• (ii) ⇒ (i). Let i_A(h_A;γ) be a filter of X, for any γ ∈ ρ([0,1]) with i_A(h_A;γ) ≠ ∅. Put h_A(x) = γ, for any x ∈ X. Then x ∈ i_A(h_A;γ). Since i_A(h_A;γ) is a filter of X, we have 1 ∈ i_A(h_A;γ) and so h_A(x) = γ ⊑ h_A(1).

Now, for any x,y ∈ X, let h_A(x * y) = γ_x*y and h_A(x) = γ_x. Put γ = γ_x*y ⊓ γ_x. Then x,x * y ∈ i_A(h_A;γ), so y ∈ i_A(h_A;γ). Hence γ ⊑ h_A(y) and so

Therefore, A ∈ HFF(X).

Theorem 9.

Let A ∈ HFF(X). Then for all a,b ∈ X and γ ∈ ρ([0,1])

Proof.

Assume that A ∈ HFF(X). Let a,b ∈ X be such that a,b ∈ i_A (h_A;γ). Then γ ⊑ h_A(a) and γ ⊑ h_A(b). Let c ∈ A(a,b). Hence a * (b * c) = 1. Now, by Proposition 3 (v), we have

Then c ∈ i_A(h_A;γ). Therefore, A(a,b) ⊆ i_A(h_A;γ)).

Corollary 10.

Let A ∈ HFF(X). Then for all γ ∈ ρ([0,1]))

Proof.

It is sufficient prove that

For this, assume that x ∈ i_A(h_A;γ). Since x * (1 * x) = 1, we have x ∈ A(x,1). Hence

Theorem 11.

Let A ∈ HFS(X). Define a Hesitant fuzzy set hA** of X as follows

where γ,η ∈ ρ([0,1]) satisfying η ⊏ ⊓_{x∉iA(hA;γ)}h_A(x). If A ∈ HFF(X), then A* ∈ HFF(X).

Proof.

Let A ∈ HFF(X) and x,y ∈ X. If x * y,x ∈ i_A(h_A;γ), then y ∈ i_A(h_A;γ) by Theorem 8 (ii). Hence

If x * y ∉ i_A(h_A;γ) or x ∉ i_A(h_A;γ), then hA**(x*y)=η or hA**(x)=η . Thus

Therefore, A* ∈ HFF(X).

Definition 10.

Hesitant fuzzy set A of X is called a hesitant fuzzy implicative filter if satisfies the following conditions:

• •

  (HFIF1) h_A(x) ⊑ h_A(1),

• •

  (HFIF2) h_A(x * (y * z)) ⊓ h_A(x * y) ⊑ h_A(x * z), for all x,y,z ∈ X.

Denote the set of all hesitant fuzzy implicative filters on X by HFIF(X). It can seen that every hesitant fuzzy implicative filter is a hesitant fuzzy filter.

Note. If |h_A(x)| = 1, for all x ∈ X, then h_A is an implicative fuzzy filter. In fact in this case we put “≤≔⊑” and “min ≔ ⊓”.

Example 6.

Let X = {1,a,b,c} with the following table:

Then (X; *, 1) is a BE–algebra. Let t₁ = {0.6,0.9}, t₂ = {0.2,0.3} and t₃ = {0.5}. Define A as

Then A is a hesitant fuzzy implicative filter.

Theorem 12.

Let X be a self distributive BE-algebra. Then every hesitant fuzzy filter is a hesitant fuzzy implicative filter.

Proof.

Let A ∈ HFF(X). Obvious that h_A(x) ⊑ h_A(1), for all x ∈ X. By using self distributivity and (HFF2), we have

Therefore, A ∈ HFIF(X).

Example 7. (Rao [⁹])

Let X = {1,a,b,c,d} with the following table:

Then (X; *, 1) is a BE-algebra but it is not self distributive because,

Let t₁ = {0.8,0.7} and t₂ = {0.4}. Define A as h_A(1) = h_A(a) = t₁ and h_A(b) = h_A(c) = h_A(d) = t₂. Then A is a hesitant fuzzy filter, but it is not a hesitant implicative filter because,

Theorem 13.

Let F be a (implicative) filter of X. Then there exists a hesitant (implicative) fuzzy filter h_A of X such that i_A(h_A;γ) = F, for some γ ∈ ρ([0,1]).

Proof.

Define hesitant fuzzy set h_A as follows

where γ ∈ ρ([0,1]) is a fixed subset. Since 1 ∈ F, we have h_A(x) ⊑ h_A(1) = γ, for all x ∈ X. Now, we consider the following cases.

• Case 1.

  If x * y,x ∈ F, then y ∈ F. Hence

  hA(x*y)⊓hA(x)=γ=hA(y).

• Case 2.

  If x * y ∈ F and x ∉ F, Then h_A(x * y) = F and h_A(x) = ∅. Hence

  hA(x*y)⊓hA(x)=γ⊓∅=∅⊑hA(y).

• Case 3.

  If x *y ∉ F and x ∈ F, Then h_A(x * y) = ∅ and h_A(x) = F. Hence

  hA(x*y)⊓hA(x)=∅⊓γ=∅⊑hA(y).

• Case 4.

  If x * y ∉ F and x ∉ F, Then h_A(x * y) = ∅ and h_A(x) = ∅. Hence

  hA(x*y)⊓hA(x)=∅⊓∅=∅⊑hA(y).

  Clearly i_A(h_A;γ) = F.

Theorem 14.

Let X be a self distributive BE-algebra and A ∈ HFF(X). Then the following conditions are equivalent:

1. (i)

   A ∈ HFIF(X),

2. (ii)

   h_A(y * (y * x)) ⊑ h_A(y * x),

3. (iii)

   h_A((z * (y * (y * x))) ⊓ h_A(z) ⊑ h_A(y * x), for all x,y,z ∈ X.

Proof.

• (i) ⇒ (ii). Let A ∈ HFIF(X). By using (HFIF1) and (BE1) we have

  hA(y*(y*x)=hA(y*(y*x))⊓hA(1)=hA(y*(y*x))⊓hA(y*y)⊑hA(y*x).

• (ii) ⇒ (iii). Let A be a hesitant fuzzy filter of X satisfying the condition (ii). By using (HFIF2) and (ii) we have

  hA(z*(y*(y*x)))⊓hA(z)⊑hA(y*(y*x))⊑hA(y*x).

• (iii) ⇒ (i). Since

  x*(y*z)=y*(x*z)≤(x*y)*(x*(x*z)).

Hence h_A(x * (y * z)) ⊑ h_A((x * y) * (x * (x * z))), by Proposition 3 (i). Thus

Therefore, A ∈ HFIF(X).

Theorem 15.

Let f : X → Y be an onto homomorphism of BE-algebras and A ∈ HFS(Y). Then A ∈ HFF(Y)(resp. A ∈ HFIF(Y)) if and only if A^f ∈ HFF(X)(resp. A^f ∈ HFIF(X)).

Proof.

Assume that A ∈ HFF(Y). For any x ∈ X, we have

Hence (HFF1) is valid. Now, let x,y ∈ X

Therefore, A^f ∈ HFF(X).

Conversely, Assume that A^f ∈ HFF(X). Let y ∈ Y. Since f is onto, there exists x ∈ X such that f(x) = y. Then

Now, let x,y ∈ Y. Then there exists a,b ∈ X such that f(a) = x and f(b) = y. Hence we have

Therefore, A ∈ HFF(Y).

Example 8.

In Example 6, sup{sup{h_A(x) : x ∈ X}} = sup{0.9,0.3,0.5} = 0.9 and so ⊤ = 1 − 0.9 = 0.1.

Theorem 16.

Let β ∈ [0, ⊤]. If A ∈ HFF(X) (resp. HFIF(X)), then h_Aβ ∈ HFF(X) (resp. HFIF(X)), too.

Proof.

Let x,y ∈ X. Then

Also, h_Aβ (x) = h_A(x) + β ⊆ h_A(1) + β = h_Aβ (1). Therefore, h_Aβ ∈ HFF(X).

Theorem 17.

If there exists β ∈ [0, ⊤] such that h_Aβ ∈ HFF(X)(resp. HFIF(X)), then h_A ∈ HFF(X) (resp. HFIF(X)), too.

Proof.

Assume that h_Aβ ∈ HFF(X), for some β ∈ [0, ⊤]. Let x, y ∈ X. Since h_Aβ (x * y) ⊓ h_Aβ (x) ⊑ h_Aβ (y), we can see that

Now, by canceling β we have

Also, by a similar way, h_A(x) ⊑ h_A(1). Therefore, h_A ∈ HFF(X).