Ulam-Hyers Stability Results for Fixed Point Problems via α-ψ-Contractive Mapping in (b)-Metric Space

Definition 1 (Bakhtin [5], Czerwik [2]). Let X be a set, and let s ≥ 1 be a given real number. A functional d : X × X → [0, ∞) is said to be a b-metric space if the following conditions are satisfied:

• (1)

  d(x, y) = 0 if and only if x = y,

• (2)

  d(x, y) = d(y, x),

• (3)

  d(x, z) ≤ s[d(x, y) + d(y, z)],

for all x, y, and z ∈ X. A pair (X, d) is called a b-metric space.

Example 2. Let X be a set with the cardinal card(X) ≥ 3. Suppose that X = X₁ ∪ X₂ is a partition of X such that card(X₁) ≥ 2. Let s > 1 be arbitrary. Then, the functional d : X × X → [0, ∞) defined by

is a b-metric on X with coefficient s > 1.

Lemma 3 (Czerwik [2]). Let (X, d) be a b-metric space. Then, ones has

Lemma 4 (Czerwik [2]). Let (X, d) be a b-metric space, and let $$. Then

Lemma 5 (Berinde [26], Rus [25]). If φ : [0, ∞)→[0, ∞) is a comparison function, then

• (1)

  each iterate φ^k of φ, k ≥ 1, is also a comparison function;

• (2)

  φ is continuous at 0;

• (3)

  φ(t) < t, for any t > 0.

Definition 6 (Berinde [26]). A function φ : [0, ∞)→[0, ∞) is said to be a (c)-comparison function if

•  

  c₁ φ is increasing,

•  

  c₂ there exist k₀ ∈ ℕ, a ∈ (0,1), and a convergent series of nonnegative terms $$ such that φ^k+1(t) ≤ aφ^k(t) + v_k, for k ≥ k₀ and any t ∈ [0, ∞).

The notion of a (c)-comparison function was improved as a (b)-comparison function by Berinde [27] in order to extend some fixed point results to the class of b-metric space.

Definition 7 (Berinde [27]). Let s ≥ 1 be a real number. A mapping φ : [0, ∞)→[0, ∞) is called a (b)-comparison function if the following conditions are fulfilled:

• (1)

  φ is monotonically increasing;

• (2)

  there exist k₀ ∈ ℕ, a ∈ (0,1), and a convergent series of nonnegative terms $$ such that s^k+1φ^k+1(t) ≤ as^kφ^k(t) + v_k, for k ≥ k₀ and any t ∈ [0, ∞).

Lemma 8 (Berinde [24]). If φ : [0, ∞)→[0, ∞) is a (b)-comparison function, then ones has the following:

• (1)

  the series $$ converges for any t ∈ ℝ₊;

• (2)

  the function b_s : [0, ∞)→[0, ∞) defined by $$, is increasing and continuous at 0.

Definition 9 (Samet et al. [1]). Let (X, d) be a metric space and f : X → X a given mapping. One says that f is an α-ψ-contractive mapping if there exist two functions α : X × X → [0, ∞) and ψ ∈ Ψ such that

Remark 10. If f : X → X satisfies the Banach contraction principle, then f is an α-ψ-contractive mapping, where α(x, y) = 1 for all x, y ∈ X and ψ(t) = kt for all t ≥ 0 and some k ∈ [0,1).

Definition 11 (Samet et al. [1]). Let f : X → X and α : X × X → [0, ∞). One says that f is α-admissible if

Example 12 (Samet et al. [1]). Let X = (0, +∞). Define f : X → X and α : X × X → [0, ∞) by

•  

  (1) f(x) = ln (x), for all x ∈ X, and

  $$ ()

Then f is α-admissible.

•  

  (2) $$, for all x ∈ X, and

  $$ ()

Then f is α-admissible.

Example 13. Let (X, ⪯) be a partially ordered set and d a metric on X such that (X, d) is complete. Let T : X → X be a nondecreasing mapping with respect to ⪯; that is, x, y ∈ X,   x⪯y⇒Tx⪯Ty. Suppose that there exists x₀ ∈ X such that x₀⪯Tx₀. Define the mapping α : X × X → [0, ∞) by

Then, T is α-admissible. Since there exists x₀ ∈ X such that x₀⪯Tx₀, we have α(x₀, Tx₀) ≥ 1. On the other hand, for all x, y ∈ X, from the monotone property of T, we have Thus T is α-admissible.

Theorem 14 (Samet et al. [1]). Let (X, d) be a complete metric space and f : X → X an α-ψ-contractive mapping satisfying the following conditions:

• (i)

  f is α-admissible;

• (ii)

  there exists x₀ ∈ X such that α(x₀, f(x₀)) ≥ 1;

• (iii)

  f is continuous.

Then, f has a fixed point; that is, there exists x^* ∈ ℱ_f(X).

Theorem 15 (Samet et al. [1]). Let (X, d) be a complete metric space and f : X → X an α-ψ-contractive mapping satisfying the following conditions:

• (i)

  f is α-admissible;

• (ii)

  there exists x₀ ∈ X such that α(x₀, f(x₀)) ≥ 1;

• (iii)

  if {x_n} is a sequence in X such that α(x_n, x_n+1) ≥ 1 for all n and x_n → x ∈ X as n → ∞, then α(x_n, x) ≥ 1 for all n.

Then, f has a fixed point; that is, there exists x^* ∈ ℱ_f(X).

Definition 16. Let (X, d) a b-metric space and f : X → X be a given mapping. We say that f is an α-ψ-contractive mapping of type-(b) if there exist two functions α : X × X → [0, ∞) and ψ ∈ Ψ_b such that

Theorem 17. Let (X, d) be a complete b-metric space with constant s > 1. Let f : X → X be an α-ψ-contractive mapping of type-(b) satisfying the following conditions:

• (i)

  f is α-admissible;

• (ii)

  there exists x₀ ∈ X such that α(x₀, f(x₀)) ≥ 1;

• (iii)

  f is continuous.

Then the fixed point equation (29) has a solution; that is, there exists x^* ∈ ℱ_f(X).

Proof. Let x₀ ∈ X such that α(x₀, f(x₀)) ≥ 1 (such a point exists from condition (ii)). Define the sequence {x_n} in X by

If x_n = x_n+1 for some n ∈ ℕ ∪ {0}, then x^* = x_n is a fixed point for f, and the proof finishes. Hence we assume that

Since f is α-admissible, we have

By induction, we get Applying the inequality (12) with x = x_n−1 and y = x_n and using (16), we obtain By induction, we get From (18) and using the triangular inequality, for all p ≥ 1, we have

Denoting $$, n ≥ 1, we obtain

Due to the assumption (14) and Lemma 8, we conclude that the series $$ is convergent. Thus there exists S = lim _n→∞S_n ∈ [0, ∞). Regarding s ≥ 1 and by (20), we obtain that {x_n} _n≥0 is a Cauchy sequence in the b-metric space (X, d). Since (X, d) is complete, there exists x^* ∈ X such that x_n → x^* as n → ∞. From the continuity of f, it follows that x_n+1 = f(x_n) → f(x^*) as n → ∞. By the uniqueness of the limit, we get x^* = f(x^*); that is, x^* is a fixed point of f.

Theorem 18. Let (X, d) be a complete b-metric space with constant s > 1. Let f : X → X be an α-ψ-contractive mapping of type-(b) satisfying the following conditions:

• (i)

  f is α-admissible;

• (ii)

  there exists x₀ ∈ X such that α(x₀, f(x₀)) ≥ 1;

• (iii)

  if {x_n} is a sequence in X such that α(x_n, x_n+1) ≥ 1 for all n and x_n → x ∈ X as n → ∞, then α(x_n, x) ≥ 1 for all n.

Then the fixed point equation (29) has a solution.

Proof. Following the proof of Theorem 17, we know that {x_n} is a Cauchy sequence in the complete b-metric space (X, d). Then, there exists x^* ∈ X such that x_n → x^* as n → ∞. On the other hand, from (16) and the hypothesis (iii), we have

Now, using the triangular inequalities, (12) and (21), we get Letting n → ∞, since ψ is continuous at t = 0, we obtain d(f(x^*), x^*) = 0; that is, x^* = f(x^*).

Theorem 19. Adding condition (H) to the hypotheses of Theorem 17 (resp., Theorem 18) one obtains uniqueness of the fixed point of f.

Proof. Suppose that x^* and y^* are two fixed points of f. From (H), there exists z ∈ X such that

Since f is α-admissible, from (23), we get Using (24) and (12), we have This implies that Then, letting n → ∞, we have Similarly, using (24) and (12), we get Using (27) and (28), the uniqueness of the limit gives us x^* = y^*. This finishes the proof.

Remark 20. Theorem 14 (resp., Theorem 15) can be derived from Theorem 17 (resp., Theorem 18) by taking s = 1. Consequently, all results in [1] can be considered as corollaries of our main results.

Definition 21. Let (X, d) be a metric space and f : X → X an operator. By definition, the fixed point equation

is called generalized Ulam-Hyers stability if and only if there exists ψ : ℝ₊ → ℝ₊ which is increasing, continuous at 0 and ψ(0) = 0 such that for every ε > 0 and for each w^* ∈ X an ε-solution of the fixed point equation (29), that is, w^*, satisfies the inequality There exists a solution x^* ∈ X of (29) such that

If there exists c > 0 such that ψ(t) = c · t, for each t ∈ ℝ₊, then the fixed point equation (29) is said to be Ulam-Hyers stability.

Theorem 22. Let (X, d) be a complete b-metric space with constant s > 1. Suppose that all the hypotheses of Theorem 19 hold and additionally that the function β : [0, ∞)→[0, ∞), β(r): = r − sψ(r) is strictly increasing and onto. Then the following hold.

• (a)

  The fixed point equation (29) is generalized Ulam-Hyers stability.

• (b)

  Fix (f) = {x^*} and if x_n ∈ X, n ∈ ℕ are such that d(x_n, f(x_n)) → 0, as n → ∞, then x_n → x^*, as n → ∞; that is, the fixed point equation (29) is well posed.

• (c)

  If g : X → X is such that there exists η ∈ [0, ∞) with

  $$ ()

then

Proof. (a) Since f : X → X is a Picard operator, so Fix (f) = {x^*}. Let ε > 0 and w^* ∈ X be a solution of (30); that is,

Since f is α-ψ-contractive mapping of type-(b) and since x^* ∈ Fix (f), from (H), there exists w^* ∈ X such that α (x^*, w^*) ≥ 1; we obtain Therefore, Consequently, the fixed point equation (29) is generalized Ulam-Hyers stability.

(b) Since f is α-ψ-contractive mapping of type-(b) and since x^* ∈ Fix (f), from (H), there exists x_n ∈ X such that α(x^*, x_n) ≥ 1; we obtain

Therefore So, the fixed point equation (29) is well posed.

(c) Since f is α-ψ-contractive mapping of type-(b) and since x^* ∈ Fix (f), from (H), there exists x ∈ X such that α(x^*, x) ≥ 1; we obtain

Therefore So, we have the following estimation: Writing (41) for x : = y^* we get