Multistep-type construction of fixed point for multivalued ρ-quasi-contractive-like maps in modular function spaces

Hudson Akewe (Department of Mathematics, University of Lagos, Lagos, Nigeria)

Hallowed Olaoluwa (Department of Mathematics, University of Lagos, Lagos, Nigeria)

Arab Journal of Mathematical Sciences

ISSN: 1319-5166

Article publication date: 13 January 2021

Issue publication date: 15 July 2021

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Abstract

Purpose

In this paper, the explicit multistep, explicit multistep-SP and implicit multistep iterative sequences are introduced in the context of modular function spaces and proven to converge to the fixed point of a multivalued map T such that PρT, an associate multivalued map, is a ρ-contractive-like mapping.

Design/methodology/approach

The concepts of relative ρ-stability and weak ρ-stability are introduced, and conditions in which these multistep iterations are relatively ρ-stable, weakly ρ-stable and ρ-stable are established for the newly introduced strong ρ-quasi-contractive-like class of maps.

Findings

Noor type, Ishikawa type and Mann type iterative sequences are deduced as corollaries in this study.

Originality/value

The results obtained in this work are complementary to those proved in normed and metric spaces in the literature.

Keywords

Citation

Akewe, H. and Olaoluwa, H. (2021), "Multistep-type construction of fixed point for multivalued ρ-quasi-contractive-like maps in modular function spaces", Arab Journal of Mathematical Sciences, Vol. 27 No. 2, pp. 189-213. https://doi.org/10.1108/AJMS-07-2020-0026

Publisher

:

Emerald Publishing Limited

License

Published in Arab Journal of Mathematical Sciences. Published by Emerald Publishing Limited. This article is published under the Creative Commons Attribution (CC BY 4.0) licence. Anyone may reproduce, distribute, translate and create derivative works of this article (for both commercial and non-commercial purposes), subject to full attribution to the original publication and authors. The full terms of this licence may be seen at http://creativecommons.org/licences/by/4.0/legalcode

1. Introduction and preliminary definitions

Modular function spaces are well-known generalizations of both function and sequence variants of many important spaces such as Calderon–Lozanovskii, Kothe, Lebesgue, Lorentz, Musielak–Orlicz, Orlicz and Orlicz–Lorentz spaces. Their applications are also very useful. There is huge interest in quasi-contractive mappings in modular function spaces mainly because of the richness of structure of modular function spaces: apart from being F-spaces in a more general setting, they are equipped with modular equivalents of norm or metric notions and also endowed with convergence in submeasure. It is worthy to mention that modular-type conditions are far more natural as their assumptions can be easily verified than their corresponding metrics or norms, especially when related to fixed-point results and applications to integral-type operators. More so, there are some fixed-point results that can be proved only using the framework of modular function spaces. Thus, results in fixed-point theory in modular function spaces and those in normed and metric spaces are complementary (see, e.g. [1]). Different researchers have proved very useful fixed-points results in the context of modular function spaces (see [1–6] for details).

The following background definitions in [1, 3, 7] are useful in proving the main results in this manuscript:

Let Ω be a nonempty set and Σ be a nontrivial σ− algebra of subsets of Ω. Let P be a δ− ring of subsets of Ω such that E∩A∈P for any E∈P and A∈Σ. Assume there exists an increasing sequence (Kn)n∈ℕ⊂P such that Ω=∪n∈ℕKn.

Let ℰ represent the linear space of all simple functions with supports from P, that is, functions s=∑k=1nαkIAk, where (αk)k∈ℕ is a sequence of real numbers, (Ak)k∈ℕ is a sequence of disjoint sets in P and IA represents the characteristic function of the set A in Ω.

Let ℳ∞ represent the space of all extended measurable functions, that is, all functions f:Ω→[−∞, ∞] such that there exists a sequence (gn)⊂ℰ satisfying |gn|≤|f| and gn(ω)→f(ω) for all ω∈Ω.

Definition 1.1.

([7]). Let ρ:ℳ∞→[0, ∞] be a nontrivial, convex and even function. ρ is said to be a regular convex function pseudomodular if:

ρ(0)=0;
ρ is monotone, that is, |f|≤|g| on Ω implies ρ(f)≤ρ(g), where f, g∈ℳ∞;
ρ is orthogonally subadditive, that is, ρ(fIA∪B)≤ρ(fIA)+ρ(fIB) for any A, B∈Ω such that A∩B≠φ, with f∈ℳ∞;
ρ has Fatou's property, that is, |fn(ω)|↑|f(ω)| for all ω∈Ω implies ρ(fn)↑ρ(f), where f∈ℳ∞;
ρ is order continuous in ℰ, that is, (gn)⊂ℰ and |gn(ω)|↓0 for all ω∈Ω implies ρ(gn)↓0.

Concepts similar to those in measure spaces are defined for function pseudomodular ρ: a set A∈Σ is said to be ρ-null if ρ(fIA)=0 ∀f∈ℰ; a property is said to hold ρ-almost everywhere (ρ-a.e.) on Σ if the set for which it does not hold is ρ-null.

The following set is defined:

ℳ(Ω, Σ, P, ρ)={f∈ℳ∞: |f|<∞ ρ−a.e.},

where each f∈ℳ∞ is actually an equivalence class of functions equal ρ-a.e. We will write ℳ instead of ℳ(Ω, Σ, P, ρ) when no confusion arises.

Definition 1.2.

([1]). Let ρ be a regular function pseudomodular.

ρ is said to be a regular function modular if ρ(f)=0 implies f=0 ρ-a.e.
ρ is said to be a regular function semimodular if ρ(αf)=0 for every α>0 implies f=0 ρ-a.e.

A regular convex function modular ρ satisfies the following properties (see [3])

ρ(f)=0 if f=0ρ -a.e.
ρ(αf)=ρ(f) for every scalar α such that |α|=1, where f∈ℳ.
ρ(αf+βg)≤αρ(f)+βρ(g) if α+β=1, α, β≥0 and f, g∈ℳ.

The class of all nonzero regular convex function modulars on Ω is denoted by ℜ.

Definition 1.3.

([7]). A convex function modular ρ defines the modular function space Lρ as

Lρ={f∈ℳ:ρ(λf)→0 as λ→0}.

Lρ is a normed linear space with respect to

|fρ|=inf{α>0:ρ(fα)≤1}

which is known as the Luxemburg norm.

Definition 1.4.

([7]). Let Lρ be a modular space. The sequence {fn}⊂Lρ is called:

ρ−convergent to f∈Lρ if ρ(fn−f)→0 as n→∞;
ρ−Cauchy, if ρ(fn−fm)→0 as n, m→∞.

Remark 1.1.

ρ−convergent sequence implies ρ−Cauchy sequence if and only if ρ satisfies the Δ2 – condition given in the definition below. However, ρ does not satisfy the triangle inequality.

Definition 1.5.

([7]). A nonzero regular convex function ρ is said to satisfy the Δ2− condition, if supn≥1ρ(2fn, Dk)→0 as k→∞ whenever {Dk}↓Ø/ and supn≥1ρ(fn, Dk)→0 as k→∞.

Definition 1.6.

([7]). Let Lρ be a modular space and D⊂Lρ.

The ρ-distance from f∈Lρ to the set D is given by:

distρ(f, D)=inf{ρ(f−h):h∈D}.

A subset D⊂Lρ is called:

ρ−closed if the ρ−limit of a ρ−convergent sequence of D always belongs to D;
ρ−a.e. closed if the ρ−a.e. limit of a ρ−a.e. convergent sequence of D always belongs to D;
ρ−compact if every sequence in D has a ρ−convergent subsequence in D;
ρ−a.e. compact if every sequence in D has a ρ−a.e. convergent subsequence in D;
ρ−bounded if diamρ(D)=sup{ρ(f−g):f, g∈D}<∞.
ρ−proximal if for each f∈Lρ there exists an element g∈D such that ρ(f−g)=distρ(f, D).

The family of nonempty ρ-bounded ρ-proximal subsets of D is denoted by Pρ(D), the family of nonempty ρ-closed ρ-bounded subsets of D by Cρ(D) and the family of ρ-compact subsets of D by Kρ(D).

Definition 1.7.

([7]). Let Lρ be a modular space. A function f∈Lρ is called a fixed point of a multivalued mapping T:Lρ→Pρ(D) if f∈Tf. The set of all fixed points of T is represented by Fρ(T) so that:

Fρ(T)={f∈Lρ:f∈Tf}.

The following set is also defined:

PρT(f)={g∈Tf:ρ(f−g)=distρ(f, Tf)}.

Zamfirescu [8] in 1972 proved the following theorem as a generalization of the Banach fixed-point theorem:

Theorem 1.1.

([8]). Let X be a complete metric space and T:X→X a Zamfirescu operator satisfying:

(1.1)d(Tx, Ty)≤hmax{d(x, y), d(x, Tx)+d(y, Ty)2, d(x, Ty)+d(y, Tx)]2},

where 0≤h<1. Then, T has a unique fixed point and the Picard iteration converges to p for any x0∈X.

Observe that in a Banach space setting, condition (1.1) implies

(1.2)‖Tx−Ty‖≤δ‖x−y‖+2δ‖x−Tx‖, δ=max{h, h2−h}∈[0, 1)

Osilike [9] used the following contractive definition: for each x, y∈X, there exist δ∈[0, 1) and L≥0 such that

(1.3)||Tx−Ty||≤δ‖x−y‖+L||x−Tx||.

Imoru and Olatinwo [10] proved some stability results using the following general contractive definition: for each x, y∈X, there exist δ∈[0, 1) and a monotone increasing function ϕ:ℝ+→ℝ+ with ϕ(0)=0 such that

(1.4)‖Tx−Ty‖≤δ‖x−y‖+ϕ(||x−Tx||).

Observe that (1.4) generalizes (1.3) and (1.2). The map T considered in (1.2)–(1.4) is single-valued. Now, we state the generalizations of (1.2)–(1.4) to multivalued mappings, as conformed to literature. (e.g. see [7]).

Let Hρ(⋅,⋅) be the ρ−Hausdorff distance on the family Cρ(Lρ) of nonempty ρ-closed ρ-bounded subsets of Lρ, that is,

Hρ(A, B)=max{supf∈Adistρ(f, B), supg∈Bdistρ(g, A)}, A, B∈Cρ(Lρ).

A multivalued map T:D→Cρ(Lρ) is said to be a:

ρ−contraction mapping if there exists a constant δ∈[0, 1) such that

(1.5)Hρ(Tf, Tg)≤δρ(f−g), ∀f, g∈D.

ρ−Zamfirescu mapping if

(1.6)Hρ(Tf, Tg)≤δρ(f−g)+2δρ(h−f), ∀f, g∈D ∀h∈Tf.

ρ−quasi-contractive mapping if

(1.7)Hρ(Tf, Tg)≤δρ(f−g)+Lρ(h−f), ∀f, g∈D ∀h∈Tf, L≥0.

ρ−quasi-contractive-like mapping if

(1.8)Hρ(Tf, Tg)≤δρ(f−g)+ϕ(ρ(h−f)), ∀f, g∈D ∀h∈Tf.

where ϕ:ℝ+→ℝ+ is a monotone increasing function with ϕ(0)=0.

Convergence and stability of fixed-point iterative sequences for single mapping T are two very vital concepts in fixed-point theory and applications. Some of the results of colossal value in this work are those in [9–20]. Rhoades and Soltuz [21] introduced the multistep iteration and proved its equivalence with Mann and Ishikawa iterations. Olaleru and Akewe [22] proved convergence of multistep iteration for a pair of mappings (S, T).

We now introduce the following iterative sequences in the framework of modular function spaces and use them to prove new fixed-point theorems.

Let T:D→Pρ(D) be a multivalued mapping.

The explicit multistep iterative sequence {fn}n=0∞⊂D is defined by:

(1.9){f0∈Dfn+1=(1−αn)fn+αnvn1, gni=(1−βni)fn+βnivni+1, i=1, 2, …, k−2gnk−1=(1−βnk−1)fn+βnk−1un, n=0, 1, 2, …

where un∈PρT(fn), vni∈PρT(gni), i=1, 2, …, k−1, and the sequences {αn}n=0∞ and {βni}n=0∞, i=1, 2, …, k−1, are in [0, 1) such that ∑n=0∞αn=∞.

The explicit Noor iterative sequence {fn}n=0∞⊂D is defined by:

(1.10){f0∈Dfn+1=(1−αn)fn+αnvn1, gn1=(1−βn1)fn+βn1vn2, gn2=(1−βn2)fn+βn2un, n=0, 1, 2, …

where un∈PρT(fn), vn1∈PρT(gn1), vn2∈PρT(gn2), and the sequences {αn}n=0∞, {βn1}n=0∞ and {βn2}n=0∞ are in [0, 1) such that ∑n=0∞αn=∞.

The explicit Ishikawa iterative sequence {fn}n=0∞⊂D is defined by:

(1.11){f0∈Dfn+1=(1−αn)fn+αnvn1, gn1=(1−βn1)fn+βn1un, n=0, 1, 2, …

where un∈PρT(fn), vn1∈PρT(gn1), and the sequences {αn}n=0∞ and {βn1}n=0∞ are in [0, 1) such that ∑n=0∞αn=∞.

The explicit Mann iterative sequence {fn}n=0∞⊂D is defined by:

(1.12){f0∈Dfn+1=(1−αn)fn+αnun, n=0, 1, 2, …

where un∈PρT(fn), {αn}n=0∞⊂[0, 1) and ∑n=0∞αn=∞.

The explicit multistep-SP iterative sequence {fn}n=0∞⊂D is defined by:

(1.13){f0∈Dfn+1=(1−αn)gn1+αnvn1gni=(1−βni)gni+1+βnivni+1, i=1, 2, …, k−2gnk−1=(1−βnk−1)fn+βnk−1un, n=0, 1, 2, …

where un∈PρT(fn), vni∈PρT(gni), i=1, 2, …, k−1, and the sequences {αn}n=0∞ and {βni}n=0∞, i=1, 2, …, k−1, are in [0, 1) such that ∑n=0∞αn=∞.

The explicit SP iterative sequence {fn}n=0∞⊂D is defined by:

(1.14){f0∈Dfn+1=(1−αn)gn1+αnvn1, gn1=(1−βn1)gn2+βn1vn2, gn2=(1−βn2)fn+βn2un, n=0, 1, 2, …

where un∈PρT(fn), vn1∈PρT(gn1), vn2∈PρT(gn2), and the sequences {αn}n=0∞, {βn1}n=0∞, and {βn2}n=0∞ are in [0, 1) such that ∑0∞αn=∞.

The implicit multistep iterative sequence {fn}n=0∞⊂D is defined by:

(1.15){f0∈Dfn+1=(1−αn)fn1+αnun+1, fni=(1−βni)fni+1+βniuni, i=1, 2, …, k−2fnk−1=(1−βnk−1)fn+βnk−1unk−1, n=0, 1, 2, …

where un+1∈PρT(fn), uni∈PρT(fni), i=1, 2, …, k−1, and the sequences {αn}n=0∞ and {βni}n=0∞, i=1, 2, …, k−1, are in [0, 1) such that ∑n=0∞αn=∞.

It should be noted that the implicit multistep iterative sequence exists if and only if T satisfies the property (I) as follows:

(I): ∀h∈D ∀β∈(0, 1) ∃f∈D ∃g∈PρT(f): f=(1−β)h+βg.

The implicit Noor iterative sequence {fn}n=0∞⊂D is defined by:

(1.16){f0∈Dfn+1=(1−αn)fn1+αnun+1, fn1=(1−βn1)fn2+βn1un1, fn2=(1−βn2)fn+βn2un2, n=0, 1, 2, …

where un+1∈PρT(fn+1), un1∈PρT(fn1), un2∈PρT(fn2), and the sequences {αn}n=0∞, {βn1}n=0∞, and {βn2}n=0∞ are in [0, 1) such that ∑n=0∞αn=∞.

The implicit Ishikawa iterative sequence {fn}n=0∞⊂D is defined by:

(1.17){f0∈Dfn+1=(1−αn)fn1+αnun+1, fn1=(1−βn1)fn+βn1un1, n=0, 1, 2, …

where un+1∈PρT(fn+1), un1∈PρT(fn1), {αn}n=0∞⊂[0, 1), {βn1}n=0∞⊂[0, 1) and ∑n=0∞αn=∞.

The implicit Mann iterative sequence {fn}n=0∞⊂D is defined by:

(1.18){f0∈Dfn+1=(1−αn)fn+αnun+1, n=0, 1, 2, …

where un+1∈PρT(fn+1), {αn}n=0∞⊂[0, 1) and ∑n=0∞αn=∞.

The following Lemmas will be needed in proving the main results.

Lemma 1.1.

([3]). Let T:D→Pρ(D) be a multivalued mapping and PρT(f)={g∈Tf:ρ(f−g)=distρ(f, Tf)}. Then the following are equivalent:

f∈Fρ(T), that is, f∈Tf.
PρT(f)={f}.
f∈F(PρT(f)), that is, f∈PρT(f). Further Fρ(T)=F(PρT(f)) where F(PρT(f)) represent the set of fixed points of PρT(f).

Lemma 1.2.

(see [13]). Let δ be a real number satisfying 0≤δ<1 and {εn}n=0∞ and {τn}n=0∞ two sequences of positive or zero numbers, less than 1, such that limn→∞εn=0 and ∑n=0∞τn=∞. Then any sequence of positive numbers {un}n=0∞ satisfying any of the following properties converges to 0:

un+1≤δun+εn for all n=0, 1, 2, …
un+1≤(1−τn)un for all n=0, 1, 2, …
un+1≤εn+(1−τn)un for all n=0, 1, 2, … if in addition, {τn}n=0∞ is bounded away from 0.

2. Convergence results

2.1 Strong convergence results for explicit multistep iterative sequences in modular function spaces

Theorem 2.1.

Let D be a ρ−closed, ρ−bounded and convex subset of a ρ−complete modular space Lρ, and T:D→Pρ(D) be a multivalued mapping such that PρT is a ρ−quasi-contractive-like mapping, satisfying contractive-like condition (1.8). Suppose that Fρ(T)≠∅. Let f0∈D and {fn}⊂D be defined by the explicit multistep iterative sequence (1.9), where the sequences {αn}n=0∞, {βni}n=0∞⊂[0, 1), (i=1, 2, …, k−1) are such that ∑0∞αn=∞. Then the explicit multistep iterative sequence (1.9) converges strongly to the fixed point of T.

Proof. Let f∈Fρ(T); from Lemma 1.1, PρT(f)={f} and Fρ(T)=F(PρT(f)).

Using the explicit multistep iterative sequence (1.9) and the convexity of ρ, we obtain the following estimate:

(2.1)ρ(fn+1−f)=ρ[(1−αn)fn+αnvn1−f]

=ρ[(1−αn)(fn−f)+αn(vn1−f)]

≤(1−αn)ρ(fn−f)+αnρ(vn1−f).

vn1∈PρT(gn1) and PρT(f)={f} imply that:

ρ(vn1−f)=distρ(vn1, PρT(f))≤Hρ(PρT(gn1), PρT(f)),

which combined with (2.1) yields:

(2.2)ρ(fn+1−f)≤(1−αn)ρ(fn−f)+αnHρ(PρT(gn1), PρT(f)).

In (1.8), letting g=gn1 and noting that PρT(f)={f} and ϕ(0)=0, we have:

(2.3)Hρ(PρT(gn1), PρT(f))≤δρ(gn1−f)+ϕ(f−h) ∀h∈PρT(f)

≤δρ(gn1−f).

Substituting (2.3) in (2.2), we obtain

(2.4)ρ(fn+1−f)≤(1−αn)ρ(fn−f)+δαnρ(gn1−f).

Similarly, from (1.9) and the convexity of ρ,

(2.5)ρ(gn1−f)=ρ[(1−βn1)fn+βn1vn2−f]

=ρ[(1−βn1)(fn−f)+βn1(vn2−f)]

≤(1−βn1)ρ(fn−f)+βn1ρ(vn2−f).

vn2∈PρT(gn2) and PρT(f)={f} imply that:

ρ(vn2−f)=distρ(vn2, PρT(f))≤Hρ(PρT(gn2), PρT(f)),

which combined with (2.5) yields:

(2.6)ρ(gn1−f)≤(1−βn1)ρ(fn−f)+βn1Hρ(PρT(gn2), PρT(f)).

In (1.8), letting g=gn2 and noting that PρT(f)={f} and ϕ(0)=0, we get:

(2.7)ρ(gn1−f)≤(1−βn1)ρ(fn−f)+δβn1ρ(gn2−f).

Similarly, an application of (1.8) and (1.9) gives

(2.8)ρ(gn2−f)≤(1−βn2)ρ(fn−f)+δβn2ρ(gn3−f).

Also, an application of (1.8) and (1.9) gives

(2.9)ρ(gn3−f)≤(1−βn3)ρ(fn−f)+δβn3ρ(gn4−f).

Substituting (2.9) in (2.8), (2.8) in (2.7) and (2.7) in (2.4), and simplifying, we obtain

(2.10)ρ(fn+1−f)≤[1−(1−δ)αn−(1−δ)δαnβn1−(1−δ)δ2αnβn1βn2

−(1−δ)δ3αnβn1βn2βn3]+δ3αnβn1βn2βn3ρ(gn4−f).

Continuing this process, an application of (1.8) and (1.9) gives

(2.11)ρ(gnk−2−f)≤(1−βnk−2)ρ(fn−f)+δβnk−2ρ(gnk−1−f).

and

(2.12)ρ(gnk−1−f)≤(1−βnk−1)ρ(fn−f)+δβnk−1ρ(fn−f).

Substituting (2.12) and (2.11) in (2.10) inductively and simplifying, we obtain

(2.13)ρ(fn+1−f)≤[1−(1−δ)αn−∑i=1k−1(1−δ)δiαnβn1βn2…βni

+δkαnβn1βn2βn3βn4…βnk−1]ρ(fn−f)

≤[1−(1−δ)αn]ρ(fn−f).

From (2.13), we inductively obtain

(2.14)ρ(fn+1−f)≤[∏m=0n(1−(1−δ)αm)]ρ(f0−f).

Using that fact that δ∈[0, 1) {αn}n=0∞⊂[0, 1) satisfying ∑n=0∞αn=∞, then from (2.14), we obtain

(2.15)limn→∞ρ(fn+1−f)≤limn→∞∏m=0n[1−(1−δ)αm]ρ(f0−f)=0.

Therefore, {fn} ρ-converges to f∈Fρ(T). The proof is complete. ▪

Since the explicit Noor (1.10), explicit Ishikawa (1.11), explicit Mann (1.12) iterative sequences are special cases of the explicit multistep iterative sequence (1.9) (see [22] for details), then Theorem 2.1 leads to the following corollary:

Corollary 2.1.

Let D be a ρ−closed, ρ−bounded and convex subset of a ρ−complete modular space Lρ, and T:D→Pρ(D) be a multivalued mapping such that PρT is a ρ−quasi-contractive-like mapping, satisfying contractive-like condition (1.8). Suppose that Fρ(T)≠Ø/. Let f0∈D and {fn}⊂D be defined by the explicit Noor (1.10), the explicit Ishikawa (1.11) and the explicit Mann (1.12) iterative sequences respectively, where the sequences {αn}n=0∞, {βn1}n=0∞, {βn2}n=0∞⊂[0,1) are such that ∑0∞αn=∞. Then:

the explicit Noor iterative sequence (1.10) converges strongly to the fixed point of T.
the explicit Ishikawa iterative sequence (1.11) converges strongly to the fixed point of T.
the explicit Mann iterative sequence (1.12) converges strongly to the fixed point of T.

2.2 Strong convergence results for explicit multistep-SP iterative sequences in modular function spaces

Theorem 2.2.

Let D be a ρ−closed, ρ−bounded and convex subset of a ρ−complete modular space Lρ, and T:D→Pρ(D) be a multivalued mapping such that PρT is a ρ−quasi-contractive-like mapping, satisfying contractive-like condition (1.8). Suppose that Fρ(T)≠Ø/. Let f0∈D and {fn}⊂D be defined by the explicit multistep-SP iterative sequence (1.13), where the sequences {αn}n=0∞, {βni}n=0∞⊂[0, 1), (i=1, 2, …, k−1) are such that ∑0∞αn=∞. Then the explicit multistep-SP iterative sequence (1.13) ρ-converges to a fixed point of T.

Proof. Let f∈Fρ(T). From Lemma 1.1, we have that PρT(f)={f} and Fρ(T)=F(PρT(f)). Using the explicit multistep-SP iterative sequence (1.13) and the convexity of ρ, we obtain the following estimate:

(2.16)ρ(fn+1−f)=ρ[(1−αn)gn1+αnvn1−f]

=ρ[(1−αn)(gn1−f)+αn(vn1−f)]

≤(1−αn)ρ(gn1−f)+αnρ(vn1−f).

Since vn1∈PρT(gn1) and PρT(f)={f}, we have

ρ(vn1−f)=distρ(vn1, PρT(f))≤Hρ(PρT(gn1), PρT(f)),

which combined with (2.16) yields:

(2.17)ρ(fn+1−f)≤(1−αn)ρ(gn1−f)+αnHρ(PρT(gn1), PρT(f)).

In (1.8), letting g=gn1 and noting that PρT(f)={f} and ϕ(0)=0, we get

(2.18)Hρ(PρT(gn1),PρT(f))≤δρ(gn1−f)+ϕ(0)=δρ(gn1−f).

Substituting (2.18) in (2.17), we obtain

(2.19)ρ(fn+1−f)≤(1−αn)ρ(gn1−f)+δαnρ(gn1−f)

=[1−(1−δ)αn]ρ(gn1−f).

Next, from (1.13) and the convexity of ρ,

(2.20)ρ(gn1−f)=ρ[(1−βn1)gn2+βn1vn2−f]

=ρ[(1−βn1)(gn2−f)+βn1(vn2−f)]

≤(1−βn1)ρ(gn2−f)+βn1ρ(vn2−f).

Since vn2∈PρT(gn2) and PρT(f)={f}, we have

ρ(vn2−f)=distρ(vn2, PρT(f))≤Hρ(PρT(gn2), PρT(f)),

which combined with (2.20) yields:

(2.21)ρ(gn1−f)≤(1−βn1)ρ(gn2−f)+βn1Hρ(PρT(gn2), PρT(f)).

Using (1.8) with g=gn2 in (2.21) and noting that ϕ(0)=0 and PρT(f)={f}, then we get the following:

(2.22)ρ(gn1−f)≤(1−βn1)ρ(gn2−f)+δβn1ρ(gn2−f)

=[1−(1−δ)βn1]ρ(gn2−f).

Similarly, an application of (1.8) and (1.13) gives

(2.23)ρ(gn2−f)≤(1−βn2)ρ(gn3−f)+δβn2ρ(gn3−f)

=[1−(1−δ)βn2]ρ(gn3−f).

Also, an application of (1.8) and (1.13) gives

(2.24)ρ(gn3−f)≤(1−βn3)ρ(gn4−f)+δβn3ρ(gn4−f)

=[1−(1−δ)βn3]ρ(gn4−f).

Continuing this process, an application of (1.8) and (1.13) gives

(2.25)ρ(gnk−2−f)≤(1−βnk−2)ρ(gnk−1−f)+δβnk−2ρ(gnk−1−f)

=[1−(1−δ)βnk−2]ρ(gnk−1−f).

and

(2.26)ρ(gnk−1−f)≤(1−βnk−1)ρ(fn−f)+δβnk−1ρ(fn−f)

=[1−(1−δ)βnk−1]ρ(fn−f).

Substituting (2.22)–(2.26) in (2.19) inductively and simplifying, we obtain

(2.27)ρ(fn+1−f)≤([1−(1−δ)αn]∏i=1k−1[1−(1−δ)βni])ρ(fn−f)

≤[1−(1−δ)αn]ρ(fn−f).

From (2.27), we inductively obtain

(2.28)ρ(fn+1−f)≤∏m=0n[1−(1−δ)αm]ρ(f0−f).

Using that fact that δ∈[0, 1) {αn}n=0∞⊂[0, 1) satisfying ∑n=0∞αn=∞, then from (2.28), we obtain

(2.29)limn→∞ρ(fn+1−f)≤limn→∞∏m=0n[1−(1−δ)αm]ρ(f0−f)=0.

Therefore, limn→∞ρ(fn−f)=0, where f∈Fρ(T). The proof is complete. ▪

Theorem 2.2 leads to the following corollary:

Corollary 2.2.

Let D be a ρ−closed, ρ−bounded and convex subset of a ρ−complete modular space Lρ, and T:D→Pρ(D) be a multivalued mapping such that PρT is a ρ−quasi-contractive-like mapping, satisfying contractive-like condition (1.8). Suppose that Fρ(T)≠∅. Let f0∈D and {fn}⊂D be defined by the explicit SP iterative sequence (1.14), with the sequences {αn}n=0∞, {βn1}n=0∞, {βn2}n=0∞⊂[0, 1) such that ∑0∞αn=∞. Then, the explicit SP iterative sequence (1.14) ρ-converges strongly to a fixed point of T.

2.3 Strong convergence results for implicit multistep iterative sequences in modular function spaces

Theorem 2.3.

Let D be a ρ−closed, ρ−bounded and convex subset of a ρ−complete modular space Lρ. Let T:D→Pρ(D) be a multivalued mapping satisfying property (I) and such that PρT is a ρ−quasi-contractive-like mapping, satisfying contractive-like condition (1.8). Suppose that Fρ(T)≠Ø/. Let f0∈D and {fn}⊂D be defined by the implicit multistep iterative sequence (1.15), where the sequences {αn}n=0∞, {βni}n=0∞⊂[0, 1) (i=1, 2, …, k−1) are such that ∑0∞αn=∞. Then, the implicit multistep iterative sequence (1.15) ρ-converges strongly to a fixed point of T.

Proof. Let f∈Fρ(T). From Lemma 1.1, we have that PρT(f)={f} and Fρ(T)=F(PρT(f)).

Using implicit multistep iterative sequence (1.15) and the convexity of ρ, we obtain the following estimate:

(2.30)ρ(fn+1−f)=ρ[(1−αn)fn1+αnun+1−f]

=ρ[(1−αn)(fn1−f)+αn(un+1−f)]

≤(1−αn)ρ(fn1−f)+αnρ(un+1−f)

Since un+1∈PρT(fn+1) and PρT(f)={f},

ρ(un+1−f)≤distρ(un+1, PρT(f))≤Hρ(PρT(fn+1), PρT(f)),

which combined with (2.30) gives

(2.31)ρ(fn+1−f)≤(1−αn)ρ(fn1−f)+αnHρ(PρT(fn+1), PρT(f)).

In (1.8), by letting g=fn+1 and noting that ϕ(0)=0 and PρT(f)={f}, we get:

(2.32)Hρ(PρT(fn+1), PρT(f))≤δρ(fn+1−f)+ϕρ(0)=δρ(fn+1−f).

Substituting (2.32) in (2.31), we obtain

ρ(fn+1−f)≤(1−αn)ρ(fn1−f)+δαnρ(fn+1−f)

That is,

(2.33)ρ(fn+1−f)≤[1−αn1−δαn]ρ(fn1−f).

Next, from (1.15) and the convexity of ρ, we have

(2.34)ρ(fn1−f)=ρ[(1−βn1fn2+βn1)un1−f]

=ρ[(1−βn1)(fn2−f)+βn1(un1−f)]

=(1−βn1)ρ(fn2−f)+βn1ρ(un1−f).

Since un1∈PρT(fn1) and PρT(f)={f},

ρ(un1, f)=distρ(un1, PρT(f))≤Hρ(PρT(fn1), PρT(f)),

which combined with (2.34) gives:

(2.35)ρ(fn1−f)≤(1−βn1)ρ(fn2−f)+βn1Hρ(PρT(fn1), PρT(f)).

By letting g=fn1 in (1.8) and noting that ϕ(0)=0 and PρT(f)={f}, we get:

(2.36)Hρ(PρT(fn1), PρT(f))≤δρ(fn1−f)+ϕρ(0)=δρ(fn1−f)

Substituting (2.36) in (2.35), we obtain

ρ(fn1−f)≤(1−βn1)ρ(fn2−f)+δβn1ρ(fn1−f)

That is,

(2.37)ρ(fn1−f)≤[1−βn11−δβn1]ρ(fn2−f).

Similarly, an application of (1.8) and (1.15) gives

(2.38)ρ(fn2−f)≤[1−βn21−δβn2]ρ(fn3−f).

(2.39)ρ(fn3−f)≤[1−βn31−δβn3]ρ(fn4−f).

⋮

(2.40)ρ(fnk−2−f)≤[1−βnk−21−δβnk−2]ρ(fnk−1−f).

(2.41)ρ(fnk−1−f)≤[1−βnk−11−δβnk−1]ρ(fn−f).

Substituting (2.37)–(2.40) in (2.33) inductively and simplifying, we obtain

(2.42)ρ(fn+1−f)≤[1−αn1−δαn][∏i=1k−11−βni1−δβni]ρ(fn−f).

Observe that

(2.43)1−αn1−δαn≤1−αn+δαn, [1−βni1−δβni]≤1−βni+δβni, i=1, …, k−1

Substituting (2.43) in (2.42) and simplifying, we obtain

(2.44)ρ(fn+1−f)≤[1−(1−δ)αn]ρ(fn−f).

From (2.44), we inductively obtain

(2.45)ρ(fn+1−f)≤∏m=0n[1−(1−δ)αm]ρ(f0−f).

Using that fact that δ∈[0, 1) {αn}n=0∞⊂[0, 1) satisfying ∑n=0∞αn=∞, then from (2.45), we obtain

(2.46)limn→∞ρ(fn+1−f)≤limn→∞∏m=0n[1−(1−δ)αm]ρ(f0−f)=0.

Therefore, limn→∞ρ(fn−f)=0, with f∈Fρ(T). The proof is complete. ▪

Theorem 2.3 leads to the following corollary:

Corollary 2.3.

Let D be a ρ−closed, ρ−bounded and convex subset of a ρ−complete modular space Lρ. Let T:D→Pρ(D) be a multivalued mapping satisfying property (I), such that PρT is a ρ−quasi-contractive-like mapping, satisfying contractive-like condition (1.8). Suppose that Fρ(T)≠∅. Let f0∈D and {fn}⊂D be defined by the implicit Noor (1.16), implicit Ishikawa (1.17) and implicit Mann (1.18) iterative sequences respectively, where the sequences {αn}n=0∞, {βn1}n=0∞, {βn2}n=0∞⊂[0, 1) are such that ∑0∞αn=∞. Then:

the implicit Noor iterative sequence (1.16) converges strongly to the fixed point of T.
the implicit Ishikawa iterative sequence (1.17) converges strongly to the fixed point of T.
the implicit Mann iterative sequence (1.18) converges strongly to the fixed point of T.

3. Stability results for strong ρ-quasi-contractive-like maps

In this section, conditions for some stability types of the explicit and implicit multistep iterative sequences are stated and backed by proofs in the framework of modular function spaces.

The first important result on T− stable single mappings was proved by Ostrowski [18] for Picard iteration. Berinde [13], presented useful explanation on how to obtain the stability of various iterative sequences. Okeke and Khan [7] gave a similar version of stability results for multivalued mapping in modular function spaces.

In this paper, we introduce two other versions of ρ-stability and attempt to relate them with the concept of ρ-stability in literature.

Definition 3.1.

Let D be a nonempty ρ−closed, ρ−bounded and convex subset of a ρ−complete modular space Lρ, and T:D→Pρ(D) be a multivalued mapping with Fρ(T)≠∅. Suppose that a fixed-point iterative sequence defined by

(3.1)fn+1=F(T, fn)

with initial guess f0∈D and F is a given function, converges to a fixed point f of T. Let {hn}n=0∞ be an arbitrary sequence in D. The fixed-point iterative sequence is said to be:

ρ-stable with respect to T if and only if

(3.2)limn→∞εn=0⇒limn→∞hn=f, where εn=ρ(hn+1−F(T, hn)).

relatively ρ-stable with respect to T if and only if

(3.3)limn→∞δn=0⇒limn→∞hn=f, where δn=ρ(hn+1−f)−ρ(F(T, hn)−f).

weakly ρ-stable with respect to T if and only if

(3.4)supλ∈(0,1]λρ(hn+1−F(T, hn)λ)→0⇒infλ∈[1,∞)λρ(hn−fλ)→0.

The term “relatively” in (2) is employed because the premise of the convergence of {hn} to f is hinged to the fact that ρ(hn+1−f) and ρ(F(T, hn)−f) get closer to each other as n increases. It is not known if this concept is directly related to ρ-stability as defined in [7]. If ρ satisfies the triangular inequality (an unwanted condition in this paper), the relation between relatively ρ-stability and ρ-stability is as follows: (1) a relative ρ-stable fixed-point iteration is ρ-stable if δn>0 for n sufficiently big since |δn|≤εn; (2) a ρ-stable fixed-point iteration is relatively ρ-stable if for n sufficiently big, δn<0 and |δn|≤εn.

However, a ρ-stable fixed-point iteration is weakly ρ-stable, hence the term “weakly.”

In this sequel, we also introduce the following concepts of strong quasi-contractions particular to modular function spaces and compatible in some sense to the newly introduced stability notions.

Definition 3.2.

Let Hρ(⋅,⋅) be the ρ-Hausdorff distance on the family Cρ(Lρ) of nonempty ρ-closed ρ-bounded subsets of Lρ, that is,

Hρ(A, B)=max{supf∈Adistρ(f, B) , supg∈Bdistρ(g, A)}, A, B∈Cρ(Lρ).

A multivalued map T:D→Cρ(Lρ) is said to be an:

m-strong ρ−contraction mapping, where m∈ℕ, if there exists a constant δ∈[0,1) such that
(3.5)Hρ(Tf, Tg)≤mδρ(f−gm), ∀f, g∈D;

(If δ=1 in (3.5), T is said to be an m-strong ρ-nonexpansive mapping)

m-strong ρ−quasi-contractive mapping, where m∈ℕ, if
(3.6)Hρ(Tf, Tg)≤mδρ(f−gm)+Lρ(h−f), ∀f, g∈D ∀h∈Tf, L≥0;

(If δ=1 in (3.6), T is said to be an m-strong ρ-quasi-contractive mapping)

m-strong ρ−quasi-contractive-like mapping, where m∈ℕ, if

(3.7)Hρ(Tf, Tg)≤mδρ(f−gm)+ϕ(ρ(h−f)), ∀f,g∈D ∀h∈Tf.

where ϕ:ℝ+→ℝ+ is a monotone increasing function with ϕ(0)=0. (If δ=1 in (3.7), T is said to be a m-strong ρ-quasi-contractive-like mapping).

Given any m∈ℕ, an m-strong ρ-contraction (resp. ρ-quasi-contractive mapping, or a ρ-quasi-contractive-like mapping) is a ρ-contraction (resp. ρ-quasi-contractive mapping, or a ρ-quasi-contractive-like mapping), thus, the convergence results in the previous section hold for m-strong ρ-quasi-contractive-like mappings. The converse is trivial when m=1.

3.1 Stability results for explicit multistep iterative sequences in modular function spaces

Theorem 3.1.

Let D be a ρ−closed, ρ−bounded and convex subset of a ρ−complete modular space Lρ, and T:D→Pρ(D) be a multivalued mapping such that PρT is an m-strong ρ-quasi-contractive-like mapping, satisfying contractive-like condition (3.7), where m∈ℕ. Suppose that Fρ(T)≠∅. Let f0∈D and {fn}⊂D be defined by the explicit multistep iterative sequence (1.9), where the sequences {αn}n=0∞,{βni}n=0∞⊂[0,1) (i=1, 2, …, k−1) are such that {αn}n=0∞ is bounded away from 0. Then, (1.9) is:

relatively ρ-stable with respect to T if m=1;
weakly ρ-stable with respect to T if m>1.
ρ-stable with respect to T if m>1 and ∀g∈D ρ(g−f)=mρ(g−fm) where f∈Fρ(T) (in this case, PρT is a ρ-quasi-contractive-like map).

Proof. Let {αn}n=0∞, {βni}n=0∞⊂[0, 1) (i=1, 2, …, k−1) be sequences such that {αn}n=0∞ is bounded away from 0.

Let {hn}n=0∞ be an arbitrary sequence in D and set:

(3.8){εn=ρ(hn+1−(1−αn)hn−αnzn1)δn=ρ(hn+1−f)−ρ((1−αn)hn+αnzn1−f)γn=supλ∈(0,1]λρ(hn+1−(1−αn)hn−αnzn1λ)sni=(1−βni)hn+βnizni+1, i=1, 2, …, k−2snk−1=(1−βnk−1)hn+βnk−1wn, n=0, 1, 2, …

where wn∈PρT(hn) and zni∈PρT(sni), i=1,2,…,k−1.

Let:

(3.9)rn,m=(1−αn)ρ(hn−fm)+αnmρ(zn1−f).

By the convexity of ρ, we have:

(3.10)ρ(hn+1−f)=δn+ρ((1−αn)hn+αnzn1−f) =δn+ρ((1−αn)(hn−f)+αn(zn1−f)) ≤δn+rn,1.

If m>1, we have:

(3.11)ρ(hn+1−fm)=ρ(αnmhn+1−(1−αn)hn−αnzn1αn+(1−αn)hn−fm+αnm(zn1−f)) ≤αnmρ(hn+1−(1−αn)hn−αnzn1αn)+rn,m ≤γnm+rn,m.

and if in addition ∀g∈D ρ(g−f)=mρ(g−fm),

(3.12)ρ(hn+1−fm)=ρ(hn+1−(1−αn)hn−αnzn1m+1−αnm(hn−f)+αnm(zn1−f)) ≤1mεn+rn,m.

Since zn1∈PρT(sn1), then ρ(zn1−f)=distρ(zn1, PρT(f))≤Hρ(PρT(sn1), PρT(f)) hence:

(3.13)rn,m≤(1−αn)ρ(hn−fm)+αnmHρ(PρT(sn1), PρT(f)).

Using (3.7) and (3.8), and noting that ϕ(0)=0, we get the following:

(3.14)rn,m≤(1−αn)ρ(hn−fm)+δαnρ(sn1−fm)

Using the convexity of ρ in (3.8), and the fact that zn2∈PρT(sn2), we have

(3.15)ρ(sn1−fm)≤(1−βn1)ρ(hn−fm)+βn1ρ(zn2−fm)

≤(1−βn1)ρ(hn−fm)+βn1mdistρ(zn2, PρT(f))

≤(1−βn1)ρ(hn−fm)+βn1mHρ(PρT(sn2), PρT(f)).

Using (3.7) and noting that ϕ(0)=0, then we get the following:

(3.16)ρ(sn1−fm)≤(1−βn1)ρ(hn−fm)+δβn1ρ(sn2−fm).

Substituting (3.16) in (3.15), then in (3.14), we obtain

(3.17)rn,m≤(1−αn)ρ(hn−fm)+δαnρ(sn1−fm)

≤(1−αn)ρ(hn−fm)+δαn(1−βn1)ρ(hn−fm)+δ2αnβn1ρ(sn2−fm)

≤[1−(1−δ)αn−αnβn1δ]ρ(hn−fm)+δ2αnβn1ρ(sn2−fm).

Similarly, successive applications of (1.8) and (3.3) give:

(3.18){ρ(sn2−fm)≤(1−βn2)ρ(hn−fm)+δβn2ρ(sn3−fm)ρ(sn3−fm)≤(1−βn3)ρ(hn−fm)+δβn3ρ(sn4−fm)ρ(snk−2−fm)≤(1−βnk−2)ρ(hn−fm)+δβnk−2ρ(snk−1−fm)ρ(snk−1−fm)≤(1−βnk−1)ρ(hn−fm)+δβnk−1ρ(hn−fm)

Substituting (3.18) in (3.17), and simplifying, we obtain

(3.19)rn,m≤[1−(1−δ)αn]ρ(hn−fm).

Hence we have the equations:

(3.20)ρ(hn+1−f)≤δn+[1−(1−δ)αn]ρ(hn−f)

and if m>1,

(3.21)ρ(hn+1−fm)≤γnm+[1−(1−δ)αn]ρ(hn−fm).

and if in addition ∀g∈D ρ(g−f)=mρ(g−fm),

(3.22)ρ(hn+1−f)≤1mεn+[1−(1−δ)αn]ρ(hn−f).

If m=1, then from (3.20) and Lemma 1.2, limn→∞δn=0⇒hn→f. Thus, the fixed-point iteration (1.9) is relatively ρ-stable.
Suppose now that m>1 and that limn→∞γn=0.
Then by (3.21) and Lemma 1.2, ρ(hn−fm)→0 and mρ(hn−fm)→0. Thus, the fixed-point iteration (1.9) is weakly ρ-stable.
Suppose that m>1 and that ∀g∈D ρ(g−f)=mρ(g−fm). If limn→∞εn=0, then by (3.22) and Lemma 1.2, hn→f. Thus, the fixed-point iteration (1.9) is ρ-stable. ∎

Theorem 3.1 leads to the following corollary:

Corollary 3.1.

Let D be a ρ−closed, ρ−bounded and convex subset of a ρ−complete modular space Lρ, and T:D→Pρ(D) be a multivalued mapping such that PρT is an m-strong ρ-quasi-contractive-like mapping, satisfying contractive-like condition (3.7), where m∈ℕ. Suppose that Fρ(T)≠Ø/. Let f0∈D and {fn}⊂D be the explicit Noor (1.10), the explicit Ishikawa (1.11) or the explicit Mann (1.12) iterative sequence, where the sequences {αn}n=0∞,{βn1}n=0∞,{βn2}n=0∞⊂[0,1) are such that {αn}n=0∞ is bounded away from 0. Then {fn} is

relatively ρ-stable with respect to T if m=1;
weakly ρ-stable with respect to T if m>1.
ρ-stable with respect to T if m>1 and ∀g∈D ρ(g−f)=mρ(g−fm) where f∈Fρ(T) (in this case, PρT is a ρ-quasi-contractive-like map).

3.2 Stability results for explicit multistep-SP iterative sequences in modular function spaces

Theorem 3.2.

Let D be a ρ−closed, ρ−bounded and convex subset of a ρ−complete modular space Lρ, and T:D→Pρ(D) be a multivalued mapping such that PρT is an m-strong ρ-quasi-contractive-like mapping, satisfying contractive-like condition (3.7), where m∈ℕ. Suppose that Fρ(T)≠∅. Let f0∈D and {fn}⊂D be defined by the explicit multistep iterative sequence (1.13), where the sequences {αn}n=0∞,{βni}n=0∞⊂[0,1) (i=1,2,…,k−1) are such that {αn}n=0∞ is bounded away from 0. Then, (1.13) is:

relatively ρ-stable with respect to T if m=1;
weakly ρ-stable with respect to T if m>1.
ρ-stable with respect to T if m>1 and ∀g∈D ρ(g−f)=mρ(g−fm) where f∈Fρ(T) (in this case, PρT is a ρ-quasi-contractive-like map).

Proof. The method of proof is similar to that of Theorem 3.1. ▪

Theorem 3.2 leads to the following corollary:

Corollary 3.2.

Let D be a ρ−closed, ρ−bounded and convex subset of a ρ−complete modular space Lρ, and T:D→Pρ(D) be a multivalued mapping such that PρT is an m-strong ρ-quasi-contractive-like mapping, satisfying contractive-like condition (3.7), where m∈ℕ. Suppose that Fρ(T)≠∅. Let f0∈D and {fn}⊂D be defined by the explicit SP iterative sequence (1.14), with the sequences {αn}n=0∞, {βn1}n=0∞, {βn2}n=0∞⊂[0, 1) such that {αn}n=0∞ is bounded away from 0. Then (1.14) is:

relatively ρ-stable with respect to T if m=1;
weakly ρ-stable with respect to T if m>1;
ρ-stable with respect to T if m>1 and ∀g∈D ρ(g−f)=mρ(g−fm) where f∈Fρ(T) (in this case, PρT is a ρ-quasi-contractive-like map).

3.3 Stability results for implicit multistep iterative sequences in modular function spaces

Theorem 3.3.

Let D be a ρ−closed, ρ−bounded and convex subset of a ρ−complete modular space Lρ. Let T:D→Pρ(D) be a multivalued mapping satisfying property (I), such that PρT is an m-strong ρ-quasi-contractive-like mapping, satisfying contractive-like condition (3.7), where m∈ℕ. Suppose that Fρ(T)≠Ø/. Let f0∈D and {fn}⊂D be defined by the implicit multistep iterative sequence (1.15), where the sequences {αn}n=0∞, {βni}n=0∞⊂[0, 1) (i=1, 2, …, k−1) are such that {αn}n=0∞ is bounded away from 0. Then, (1.15) is:

relatively ρ-stable with respect to T if m=1;
weakly ρ-stable with respect to T if m>1.
ρ-stable with respect to T if m>1 and ∀g∈D ρ(g−f)=mρ(g−fm) where f∈Fρ(T) (in this case, PρT is a ρ-quasi-contractive-like map).

Proof.

Let {αn}n=0∞, {βni}n=0∞⊂[0, 1) be sequences such that {αn}n=0∞ is bounded away from 0. Suppose f∈Fρ(T). Let {hn}n=0∞ is an arbitrary sequence and set:

(3.23){εn=ρ(hn+1−(1−αn)hn1−αnzn+1),δn=ρ(hn+1−f)−ρ((1−αn)hn1+αnzn+1−f),γn=supλ∈(0,1]λρ(hn+1−(1−αn)hn1−αnzn+1λ)hni=(1−βni)hni+1+βnizni, i=1, 2, …, k−2hnk−1=(1−βnk−1)hn+βnk−1znk−1, n=0, 1, 2, …,

where zn+1∈PρT(hn+1), zni∈PρT(hni), i=1, 2, …, k−1.

Let:

(3.24)rn,m=(1−αn)ρ(hn1−fm)+αnmρ(zn+1−f).

By the convexity of ρ, we have:

(3.25)ρ(hn+1−f)=δn+ρ((1−αn)hn1+αnzn+1−f) =δn+ρ((1−αn)(hn1−f)+αn(zn+1−f)) ≤δn+rn,1.

If m>1, we have:

(3.26)ρ(hn+1−fm)=ρ(αnmhn+1−(1−αn)hn1−αnzn+1αn+(1−αn)hn1−fm+αnm(zn+1−f)) ≤αnmρ(hn+1−(1−αn)hn1−αnzn+1αn)+rn,m ≤γnm+rn,m.

and if in addition ∀g∈D ρ(g−f)=mρ(g−fm),

(3.27)ρ(hn+1−fm)=ρ(hn+1−(1−αn)hn1−αnzn+1m+1−αnm(hn1−f)+αnm(zn+1−f)) ≤1mεn+rn,m.

Since zn+1∈PρT(hn+1), from (3.24) and (3.7) we have that:

(3.28)rn,m=(1−αn)ρ(hn1−fm)+αnmρ(zn+1−f) =(1−αn)ρ(hn1−fm)+αnmdistρ(zn+1, PρT(f)) ≤(1−αn)ρ(hn1−fm)+αnmHρ(PρT(hn+1), PρT(f)) ≤(1−αn)ρ(hn1−fm)+δαnρ(hn+1−fm).

Using the convexity of ρ in (3.23), and the fact that zn1∈PρT(hn1), we have

ρ(hn1−fm)≤(1−βn1)ρ(hn2−fm)+βn1ρ(zn1−fm) ≤(1−βn1)ρ(hn2−fm)+βn1mdistρ(zn1, PρT(f)) ≤(1−βn1)ρ(hn2−fm)+βn1mHρ(PρT(hn1), PρT(f)) ≤(1−βn1)ρ(hn2−fm)+δβn1ρ(hn1−fm).

Thus:

(3.29)ρ(hn1−fm)≤[1−βn11−δβn1]ρ(hn2−fm).

Similarly, we have the following:

(3.30)ρ(hn2−fm)≤[1−βn21−δβn2]ρ(hn3−fm)

⋮

(3.31)ρ(hnk−2−fm)≤[1−βnk−21−δβnk−2]ρ(hnk−1−fm)

(3.32)ρ(hnk−1−fm)≤[1−βnk−11−δβnk−1]ρ(hn−fm)

Substituting (3.29) – (3.32), and simplifying, we obtain

(3.33)rn,m≤(1−αn)[∏i=1m1−βni−11−δβni−1]ρ(hn−fm)+δαnρ(hn+1−fm)≤(1−αn)ρ(hn−fm)+δαnρ(hn+1−fm).

Hence, substituting (3.33) in (3.25)–(3.27), we have the equations:

(3.34)ρ(hn+1−f)≤δn+(1−αn1−δαn)ρ(hn−f)

and if m>1,

(3.35)ρ(hn+1−fm)≤γnm+(1−αn1−δαn)ρ(hn−fm).

and if in addition ∀g∈D ρ(g−f)=mρ(g−fm),

(3.36)ρ(hn+1−fm)≤εnm+(1−αn1−δαn)ρ(hn−fm).

If m=1, then from (3.34) and Lemma 1.2, limn→∞δn=0⇒hn→f. Thus the fixed-point iteration (1.15) is relatively ρ-stable.
Suppose now that m>1 and that limn→∞γn=0.
Then by (3.35) and Lemma 1.2, ρ(hn−fm)→0. Thus mρ(hn−fm)→0. Thus, the fixed-point iteration (1.15) is weakly ρ-stable.
Suppose that m>1 and that ∀g∈D ρ(g−f)=mρ(g−fm). If limn→∞εn=0, then by (3.36) and Lemma 1.2, hn→f. Thus, the fixed-point iteration (1.15) is ρ-stable. ▪

Theorem 3.3 leads to the following corollary:

Corollary 3.3.

Let D be a ρ−closed, ρ−bounded and convex subset of a ρ−complete modular space Lρ. Let T:D→Pρ(D) be a multivalued mapping satisfying property (I), such that PρT is an m-strong ρ-quasi-contractive-like mapping, satisfying contractive-like condition (3.7), where m∈ℕ. Suppose that Fρ(T)≠∅. Let f0∈D and {fn}⊂D be defined by the implicit Noor (1.16), implicit Ishikawa (1.17), implicit Mann (1.18) iterative sequence respectively, where the sequences {αn}n=0∞,{βn1}n=0∞,{βn2}n=0∞⊂[0,1) are such that {αn}n=0∞ is bounded away from 0. Then, (1.16)–(1.18) are:

relatively ρ-stable with respect to T if m=1;
weakly ρ-stable with respect to T if m>1.
ρ-stable with respect to T if m>1 and ∀g∈D ρ(g−f)=mρ(g−fm) where f∈Fρ(T) (in this case, PρT is a ρ-quasi-contractive-like map).

3.3.1 Numerical example

Let M[0,1] be the collection of all real-valued measurable functions on [0,1] and ρ:M[0, 1]→ℝ a convex function modular defined by ρ(f)=∫01|f| ∀f∈M[0, 1]. Let D={f∈Lρ: 0≤f(x)≤2 ∀x∈[0, 1]} be a subset of the modular function space Lρ=M[0, 1] defined by ρ. D is nonempty, closed and convex.

Define map T:D→Pρ(D) by Tf={δf}, where δ=0.9. T satisfies property (I), has a unique fixed point f=0 (since 0∈T(0)), and PρT is a ρ-contraction, with PρT(f)={Tf} ∀f∈D. In fact, PρT is an m-strong ρ-strong contraction for all m∈ℕ, since ρ(g)=mρ(gm).

We present the results of convergence to f=0 of a multistep iterative sequence (1.9), an explicit multistep-SP iterative sequence (1.13) and an implicit multistep iterative sequence (1.15) using MATLAB. The parameters used are the following: f0(x)=0.5x+0.95 ∀x∈[0, 1], αn=14+1n+2, βni=1n+2 for i=1, 2, …, k−1, where k=11 and n=1,2,…,100 (see Tables 1 and 2).

For this example, the explicit multistep-SP sequence seems to converge to the fixed point f=0 slightly faster than the implicit multistep sequence, with approximates ρ(fn−f) under 10−2 at n=17 and n=25 respectively, while the explicit multistep sequence is considerably slower, with ρ(fn−f)<10−2 only from n=79.

4. Conclusion

In Theorems 2.1–2.3, the fixed points of multivalued maps T with a ρ-contractive-like associate map PρT in modular spaces are successfully approximated, with supporting proofs and a numerical example, via the explicit multistep (1.9), the explicit multistep-SP (1.13) and the implicit multistep (1.15) iterative sequences. These sequences involve more steps (k≥1) than the iterations considered in [6, 7].

In an attempt to prove the stability of these iterations, a new approach is used to match the convexity structure of ρ: the concepts of relative ρ-stability (3.3) and weak ρ-stability (3.4) are introduced for the first time in literature, as well as the notions of m-strong ρ-quasi-contraction types (3.5)–(3.7), where m∈ℕ, which coincide with quasi-contraction types when ρ is nonnegative homogeneous. Theorems 3.1–3.3 then state conditions under which schemes (1.9), (1.13) and (1.15) are ρ-stable, relatively ρ-stable and weakly ρ-stable, when PρT is an m-strong ρ-quasi-contractive-like mapping. The proofs of this theorem are fundamentally different from those of parallel results in metric spaces as they elegantly cut out the use of triangle inequality.

Table 1

Convergence

N	Explicit multistep fn(x)	Explicit multistep-SP fn(x)	Implicit multistep fn(x)
0	0.5000x + 0.9500	0.5000x + 0.9500	0.5000x + 0.9500
1	0.4583x + 0.8708	0.3470x + 0.6593	0.3904x + 0.7418
⋮	⋮	⋮	⋮
16	0.2461x + 0.4676	0.0443x + 0.0842	0.0695x + 0.1320
17	0.2383x + 0.4527	0.0410x + 0.0779	0.0648x + 0.1230
⋮	⋮	⋮	⋮
24	0.1917x + 0.3642	0.0252x + 0.0480	0.0417x + 0.0792
25	0.1860x + 0.3534	0.0237x + 0.0450	0.0394x + 0.0748
⋮	⋮	⋮	⋮
60	0.0690x + 0.1311	0.0043x + 0.0081	0.0080x + 0.0152
61	0.0671x + 0.1276	0.0041x + 0.0078	0.0077x + 0.0146
⋮	⋮	⋮	⋮
77	0.0435x + 0.0827	0.0022x + 0.0042	0.0042x + 0.0080
78	0.0424x + 0.0805	0.0021x + 0.0040	0.0041x + 0.0077
79	0.0412x + 0.0783	0.0020x + 0.0039	0.0039x + 0.0075
⋮	⋮	⋮	⋮
101	0.0229x + 0.0435	0.0009x + 0.0017	0.0018x + 0.0035

Table 2

Approximates ρ(fn−f)

N	Explicit multistep	Explicit multistep-SP	Implicit multistep
0	1.2	1.2	1.2
⋮	⋮	⋮	⋮
16	0.5906	0.1064	0.1667
17	0.5719	0.0984	0.1554
⋮	⋮	⋮	⋮
24	0.4601	0.0606	0.1001
25	0.4464	0.0569	0.0945
⋮	⋮	⋮	⋮
60	0.1656	0.0103	0.0192
61	0.1611	0.0099	0.0184
⋮	⋮	⋮	⋮
77	0.1044	0.0053	0.0101
78	0.1016	0.0051	0.0098
79	0.0990	0.0049	0.0094
⋮	⋮	⋮	⋮
101	0.0550	0.0022	0.0044

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Corresponding author

Hallowed Olaoluwa can be contacted at: holaoluwa@unilag.edu.ng

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1. Introduction and preliminary definitions

2. Convergence results

2.1 Strong convergence results for explicit multistep iterative sequences in modular function spaces

2.2 Strong convergence results for explicit multistep-SP iterative sequences in modular function spaces

2.3 Strong convergence results for implicit multistep iterative sequences in modular function spaces

3. Stability results for strong ρ-quasi-contractive-like maps

3.1 Stability results for explicit multistep iterative sequences in modular function spaces

3.2 Stability results for explicit multistep-SP iterative sequences in modular function spaces

3.3 Stability results for implicit multistep iterative sequences in modular function spaces

3.3.1 Numerical example

4. Conclusion

References

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