On rate of convergence of various iterative schemes

Hussain, Nawab; Rafiq, Arif; Damjanović, Boško; Lazović, Rade

doi:10.1186/1687-1812-2011-45

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Published: 05 September 2011

On rate of convergence of various iterative schemes

Nawab Hussain¹,
Arif Rafiq²,
Boško Damjanović³ &
…
Rade Lazović⁴

Fixed Point Theory and Applications volume 2011, Article number: 45 (2011) Cite this article

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Abstract

In this note, by taking an counter example, we prove that the iteration process due to Agarwal et al. (J. Nonlinear Convex. Anal. 8 (1), 61-79, 2007) is faster than the Mann and Ishikawa iteration processes for Zamfirescu operators.

1 Introduction

For a nonempty convex subset C of a normed space E and T : C → C, (a) the Mann iteration process [1] is defined by the following sequence{x_n}:

\{\begin{matrix} x_{0} \in C, \\ x_{n + 1} = (1 - b_{n}) x_{n} + b_{n} T x_{n}, n \geq 0, \end{matrix} (M_{n},)

where {b_n} is a sequence in [0, 1].

(b)
the sequence {x_n} defined by
$\{\begin{matrix} x_{0} \in C, \\ y_{n} = (1 - {b^{'}}_{n}) x_{n} + {b^{'}}_{n} T x_{n}, \\ x_{n + 1} = (1 - b_{n}) x_{n} + b_{n} T y_{n}, n \geq 0, \end{matrix} (I_{n},)$

where {b_n}, ${b_{n}^{'}}$ are sequences in [0, 1] is known as the Ishikawa [2] iteration process.

(c)
the sequence {x_n} defined by
$\{\begin{matrix} x_{0} \in C, \\ y_{n} = (1 - {b^{'}}_{n}) x_{n} + {b^{'}}_{n} T x_{n}, \\ x_{n + 1} = (1 - b_{n}) T x_{n} + b_{n} T y_{n}, n \geq 0, \end{matrix} (A R S_{n},)$

where {b_n}, ${b_{n}^{'}}$ are sequences in [0, 1] is known as the Agarwal et al. [3] iteration process.

Definition 1. [4] Suppose that {a_n} and {b_n} are two real convergent sequences with limits a and b, respectively. Then, {a_n} is said to converge faster than {b_n} if

lim_{n \to \infty} |\frac{a_{n} - a}{b_{n} - b}| = 0 .

Theorem 2. [5] Let (X, d) be a complete metric space, and T : X → X a mapping for which there exist real numbers, a, b, and c satisfying 0 < a < 1, 0 < b, $c < \frac{1}{2}$ such that for each pair x, y ∈ X, at least one of the following is true:

(z 1) d(Tx, Ty) ≤ ad(x, y),

(z 2) d(Tx, Ty) ≤ b [d(x, Tx) + d(y, Ty)],

(z 3) d(Tx, Ty) ≤ c [d(x, Ty) + d(y, Tx)].

Then, T has a unique fixed point p and the Picard iteration ${x_{n}}_{n = 1}^{\infty}$ defined by

x_{n + 1} = T x_{n}, n = 0, 1, 2, \dots,

converges to p, for any x₀ ∈ X.

Remark 3. An operator T that satisfies the contraction conditions (z 1) - (z 3) of Theorem 2 will be called a Zamfirescu operator [[4, 6, 7]] and is denoted by Z.

In [6, 7], Berinde introduced a new class of operators on a normed space E satisfying

| | T x - T y | | \leq δ | | x - y | | + L | | T x - x | | (B)

for any x, y ∈ E, 0 ≤ δ < 1 and L ≥ 0. He proved that this class is wider than the class of Zamfiresu operators.

The following results are proved in [6, 7].

Theorem 4. [7] Let C be a nonempty closed convex subset of a normed space E. Let T : C → C be an operator satisfying (B). Let {x_n} be defined through the iterative process (M_n). If F (T) ≠ Ø and $\sum b_{n} = \infty$ , then {x_n} converges strongly to the unique fixed point of T.

Theorem 5. [6] Let C be a nonempty closed convex subset of an arbitrary Banach space E and T : C → C be an operator satisfying (B). Let {x_n} be defined through the iterative process I_n and x₀ ∈ C, where {b_n} and ${b_{n}^{'}}$ are sequences of positive numbers in [0, 1] with {b_n} satisfying $\sum b_{n} = \infty$ . Then {x_n} converges strongly to the fixed point of T.

The following theorem was presented in [8].

Theorem 6. Let C be a closed convex subset of an arbitrary Banach space E. Let the Mann and Ishikawa iteration processes denoted by M_n and I_n, respectively, with {b_n} and ${b_{n}^{'}}$ be real sequences satisfying (i) 0 ≤ b_n, $b_{n}^{'} \leq 1$ , and (ii) $\sum b_{n} = \infty$ . Then, M_n and I_n converge strongly to the unique fixed point of a Zamfirescu operator T : C → C, and moreover, the Mann iteration process converges faster than the Ishikawa iteration process to the fixed point of T.

Remark 7. In [9], Qing and Rhoades, by taking a counter example, showed that the Ishikawa iteration process is faster than the Mann iteration process for Zamfirescu operators. Thus, Theorem in [8] and the presentation in [9] contradict to each other (see also [10]).

In this note, we establish a general theorem to approximate fixed points of quasi-contractive

operators in a Banach space through the iteration process ARS_n, due to Agarwal et al. [3]. Our result generalizes and improves upon, among others, the corresponding results of Babu and Prasad [8] and Berinde [4, 6, 7].

We also prove that the iteration process ARS_n is faster than the Mann iteration process M_n and the Ishikawa iteration process I_n for Zamfirescu operators.

2 Main results

We now prove our main results.

Theorem 8. Let C be a nonempty closed convex subset of an arbitrary Banach space E and T : C → C be an operator satisfying (B). Let {x_n} be defined through the iterative process ARS_n and x₀ ∈ C, where {b_n}, ${b_{n}^{'}}$ are sequences in [0, 1] satisfying $\sum b_{n} = \infty$ . Then, {x_n} converges strongly to the fixed point of T.

Proof. Assume that F(T) ≠ Ø and w ∈ F(T), then using (ARS_n), we have

\begin{align} | | x_{n + 1} - w | | & = | | (1 - b_{n}) T x_{n} + b_{n} T y_{n} - w | | & (1) \\ = | | (1 - b_{n}) (T x_{n} - w) + b_{n} (T y_{n} - w) | | & (2) \\ \leq (1 - b_{n}) | | T x_{n} - w | | + b_{n} | | T y_{n} - w | | . & (3) \\ (4) \end{align}

(2.1)

Now using (B) with x = w, y = x_n, and then with x = w, y = y_n, we obtain the following two inequalities,

| | T x_{n} - w | | \leq δ | | x_{n} - w | |,

(2.2)

and

| | T y_{n} - w | | \leq δ | | y_{n} - w | | .

(2.3)

By substituting (2.2) and (2.3) in (2.1), we obtain

| | x_{n + 1} - w | | \leq (1 - b_{n}) δ | | x_{n} - w | | + b_{n} δ | | y_{n} - w | | .

(2.4)

In a similar fashion, again by using (ARS_n), we can get

| | y_{n} - w | | \leq (1 - (1 - δ) b_{n}^{'}) | | x_{n} - w | | .

(2.5)

From (2.4) and (2.5), we have

| | x_{n + 1} - w | | \leq [1 - (1 - δ) b_{n} (1 + δ b_{n}^{'})] | | x_{n} - w | | .

(2.6)

It may be noted that for δ ∈ [0, 1) and {η_n} ∈ [0, 1], the following inequality holds:

1 \leq 1 + δ η_{n} \leq 1 + δ .

(2.7)

From (2.6) and (2.7), we get

| | x_{n + 1} - w | | \leq (1 - (1 - δ) b_{n}) | | x_{n} - w | | .

(2.8)

By (2.8) we inductively obtain

| | x_{n + 1} - w | | \leq \prod_{k = 0}^{n} [1 - δ (1 - δ) b_{k}] | | x_{0} - w | |, n = 0, 1, 2, \dots

(2.9)

Using the fact that 0 ≤ δ < 1, 0 ≤ b_n ≤ 1, and $\sum b_{n} = \infty$ , it results that

lim_{n \to \infty} \prod_{k = 0}^{n} [1 - δ (1 - δ) b_{k}] = 0,

which by (2.9) implies

lim_{n \to \infty} | | x_{n + 1} - w | | = 0 .

Consequently x_n → w ∈ F and this completes the proof. □

Now by an counter example, we prove that the iteration process ARS_n due to Agarwal et al. [3] is faster than the Mann and Ishikawa iteration processes for Zamfirescu operators.

Example 9. [9] Suppose $T : [0, 1] \to [0, 1] : = \frac{1}{2} x$ , $b_{n} = 0 = b_{n}^{'}$ , n = 1, 2,..., 15. $b_{n} = \frac{4}{\sqrt{n}} = b_{n}^{'}$ , n ≥ 16.

It is clear that T is a Zamfirescu operator with a unique fixed point 0. Also, it is easy to see that Example 9 satisfies all the conditions of Theorem 8.

Proof. Since $b_{n} = 0 = b_{n}^{'}$ , n = 1, 2,..., 15, so M_n = x₀ = I_n = ARS_n, n = 1, 2,..., 16. Suppose x₀ ≠ 0. For M_n, I_n and ARS_n iteration processes, we have

\begin{align} M_{n} & = (1 - b_{n}) x_{n} + b_{n} T x_{n} & (1) \\ = (1 - \frac{4}{\sqrt{n}}) x_{n} + \frac{4}{\sqrt{n}} \frac{1}{2} x_{n} & (2) \\ = (1 - \frac{2}{\sqrt{n}}) x_{n} & (3) \\ = \cdot \cdot \cdot & (4) \\ = \prod_{i = 16}^{n} (1 - \frac{2}{\sqrt{i}}) x_{0}, & (5) \\ (6) \end{align}

\begin{align} I_{n} & = (1 - b_{n}) x_{n} + b_{n} T ((1 - {b^{'}}_{n}) x_{n} + {b^{'}}_{n} T x_{n}) & (1) \\ = (1 - \frac{4}{\sqrt{n}}) x_{n} + \frac{4}{\sqrt{n}} \frac{1}{2} (1 - \frac{2}{\sqrt{n}}) x_{n} & (2) \\ = (1 - \frac{2}{\sqrt{n}} - \frac{4}{n}) x_{n} & (3) \\ = \cdot \cdot \cdot & (4) \\ = \prod_{i = 16}^{n} (1 - \frac{2}{\sqrt{i}} - \frac{4}{i}) x_{0}, & (5) \\ (6) \end{align}

and

\begin{align} A R S_{n} & = (1 - b_{n}) T x_{n} + b_{n} T ((1 - {b^{'}}_{n}) x_{n} + {b^{'}}_{n} T x_{n}) & (1) \\ = (1 - \frac{4}{\sqrt{n}}) \frac{x_{n}}{2} + \frac{4}{\sqrt{n}} \frac{1}{2} (1 - \frac{2}{\sqrt{n}}) x_{n} & (2) \\ = (\frac{1}{2} - \frac{4}{n}) x_{n} & (3) \\ = \cdot \cdot \cdot & (4) \\ = \prod_{i = 16}^{n} (\frac{1}{2} - \frac{4}{i}) x_{0} . & (5) \\ (6) \end{align}

Now consider

\begin{align} |\frac{A R S_{n} - 0}{M_{n} - 0}| & = |\frac{\prod_{i = 16}^{n} (\frac{1}{2} - \frac{4}{i}) x_{0}}{\prod_{i = 16}^{n} (1 - \frac{2}{\sqrt{i}}) x_{0}}| & (1) \\ = |\frac{\prod_{i = 16}^{n} (\frac{1}{2} - \frac{4}{i})}{\prod_{i = 16}^{n} (1 - \frac{2}{\sqrt{i}})}| & (2) \\ = |\prod_{i = 16}^{n} (1 - \frac{\frac{1}{2} - \frac{2}{\sqrt{i}} + \frac{4}{i}}{(1 - \frac{2}{\sqrt{i}})})| & (3) \\ = |\prod_{i = 16}^{n} (1 - \frac{1}{2 \sqrt{i}} \frac{i - 4 \sqrt{i} + 8}{\sqrt{i} - 2})| . & (4) \\ (5) \end{align}

It is easy to see that

\begin{align} 0 & \leq lim_{n \to \infty} \prod_{i = 16}^{n} (1 - \frac{1}{2 \sqrt{i}} \frac{i - 4 \sqrt{i} + 8}{\sqrt{i} - 2}) & (1) \\ \leq lim_{n \to \infty} \prod_{i = 16}^{n} (1 - \frac{1}{i}) & (2) \\ = lim_{n \to \infty} \frac{15}{n} & (3) \\ = 0 . & (4) \\ (5) \end{align}

Hence

lim_{n \to \infty} |\frac{A R S_{n} - 0}{M_{n} - 0}| = 0 .

Thus, the iteration process due to Agarwal et al. [3] converges faster than the Mann iteration process to the fixed point 0 of T.

Similarly

\begin{align} |\frac{A R S_{n} - 0}{I_{n} - 0}| & = |\frac{\prod_{i = 16}^{n} (\frac{1}{2} - \frac{4}{i}) x_{0}}{\prod_{i = 16}^{n} (1 - \frac{2}{\sqrt{i}} - \frac{4}{i}) x_{0}}| & (1) \\ = |\frac{\prod_{i = 16}^{n} (\frac{1}{2} - \frac{4}{i})}{\prod_{i = 16}^{n} (1 - \frac{2}{\sqrt{i}} - \frac{4}{i})}| & (2) \\ = |\prod_{i = 16}^{n} (1 - \frac{\frac{1}{2} - \frac{2}{\sqrt{i}}}{(1 - \frac{2}{\sqrt{i}} - \frac{4}{i})})| & (3) \\ = |\prod_{i = 16}^{n} (1 - \frac{\sqrt{i}}{2} \frac{i - 4}{i - 2 \sqrt{i} - 4})|, & (4) \\ (5) \end{align}

with

\begin{align} 0 & \leq lim_{n \to \infty} \prod_{i = 16}^{n} (1 - \frac{\sqrt{i}}{2} \frac{\sqrt{i} - 4}{i - 2 \sqrt{i} - 4}) & (1) \\ \leq lim_{n \to \infty} \prod_{i = 16}^{n} (1 - \frac{1}{i}) & (2) \\ = lim_{n \to \infty} \frac{15}{n} & (3) \\ = 0, & (4) \\ (5) \end{align}

implies

lim_{n \to \infty} |\frac{A R S_{n} - 0}{I_{n} - 0}| = 0 .

Thus, the iteration process due to Agarwal et al. [3] converges faster than the Ishikawa iteration process to the fixed point 0 of T. □

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Acknowledgements

Nawab Hussain gratefully acknowledges the support provided by King Abdulaziz University during this research. Boško Damjanović and Rade Lazović are thankful to the Ministry of Science, Technology and Development, Republic of Serbia.

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Authors and Affiliations

Department of Mathematics, King Abdulaziz University, Jeddah, Saudi Arabia
Nawab Hussain
Department of Mathematics, COMSATS Institute of Information Technology, Islamabad, Pakistan
Arif Rafiq
Faculty of Agriculture, Nemanjina 6, Belgrade, Serbia
Boško Damjanović
Faculty of Organizational Science, Jove Ili ća 154, Belgrade, Serbia
Rade Lazović

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Nawab Hussain
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Arif Rafiq
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The four authors have equitably contributed in obtaining the new results presented in this article. All authors read and approved the final manuscript.

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Hussain, N., Rafiq, A., Damjanović, B. et al. On rate of convergence of various iterative schemes. Fixed Point Theory Appl 2011, 45 (2011). https://doi.org/10.1186/1687-1812-2011-45

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Received: 11 February 2011
Accepted: 05 September 2011
Published: 05 September 2011
DOI: https://doi.org/10.1186/1687-1812-2011-45

On rate of convergence of various iterative schemes

Abstract

1 Introduction

2 Main results

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Acknowledgements

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