The convergence of Mann iteration with errors is equivalent to the convergence of Ishikawa iteration with errors

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This is a reprint of Lecturas Matemáticas Volumen 25 (2004), páginas 5 13 The convergence of Mann iteration with errors is equivalent to the convergence of Ishikawa iteration with errors Stefan M. Şoltuz Cluj-Napoca, Romania

Lecturas Matemáticas Volumen 25 (2004), páginas 5 13 The convergence of Mann iteration with errors is equivalent to the convergence of Ishikawa iteration with errors Ştefan M. Şoltuz Cluj-Napoca, Romania Abstract. We prove that the convergence of Mann iteration with errors and the convergence of Ishikawa iteration with errors are equivalent when dealing with Lipschitzian strongly pseudocontractive maps. Key words and phrases. Mann iteration with errors, Ishikawa iteration with errors, strongly pseudocontraction, strongly accretive and accretive. 1991 Mathematics Subject Classification. Primary (2000): 47H10. Resumen. Se demuestra que en un espacio de Banach real la convergencia de la iteración de Mann con errores es equivalente la convergencia de la iteración de Ishikawa con errores cuando se trabaja con aplicaciones lipschitzianas fuertemente seudocontractivas, fuertemente acretivas y acretivas. 1. Preliminaries Let X be a real Banach space and B be a nonempty, convex subset of X. LetT : B X be a map and u 1,x 1 B. Let us denote by F (T )

6 Stefan M. Şoltuz tne fixed points of T. We consider the iteration (see [10]): u n+1 =(1 α n )u n + α n Tu n + e n. (M) The sequence (α n ) n (0, 1), is such that lim α n =0and α n =. A prototype is α n = 1/n, n 1. The errors (e n ) X satisfy e n <. This iteration is known as Mann iteration with errors. We consider the following iteration (see [10]): x n+1 =(1 α n )x n + α n Ty n + p n, y n =(1 β n )x n + β n Tx n + q n, n =1, 2,.... (I) The sequences (α n ), (β n ) (0, 1), are such that lim α n = 0, lim β n = 0, and α n =. Furthermore, the sequence (α n ) is the same (M) and (I). For β n =0,n N we get Mann iteration with errors. The errors (p n ) and (q n ) X satisfy p n <, q n <. When p n = q n =0,n N, we deal with Ishikawa iteration (see [7]). Mann and Ishikawa iterations with errors (M) and (I) were criticized in [17]. The main argument was that the errors should be bounded sequences without being necessary convergent to zero. New iteration types were introduced in [17]. According to [5], these new iterations are redundant (i.e. lead us to (M) and (I)), when the operator T has a bounded range. In [12] an example can be found in which iteration (I) but not (M) converges. The map T is a Lipschitz pseudocontraction, without being strongly pseudocontractive. In this note we prove that the convergence of Mann iteration is actually equivalent to the convergence of Ishikawa iteration when dealing with Lipschitz strong pseudocontractions. The following definition is in [9].

Convergence of Mann iteration with errors 7 Definition 1. Let X be a real Banach space and let B be a nonempty subset of X. A map T : B B is called strongly pseudocontractive if there exists k (0, 1) such that, denoting with I the identity map of X, we have x y x y + r[(i T ki)x (I T ki)y], (1) for all x, y B, and all r>0. The following lemma is in [10]. Lemma 2. Let (a n ) be a nonnegative sequence satisfying a n+1 (1 λ n )a n + σ n + c n, (2) where λ n (0, 1), σ n = ε n λ n,andε n 0, for all n N, lim ε n =0, λ n = and c n <. Then lim a n =0. 2. The convergence of Mann iteration with errors is equivalent to the convergence of Ishikawa iteration with errors We are now able to establish our the main result: Theorem 3. Let X be a Banach space, B be a nonempty, bounded, convex and closed subset of X, and T : B X be a Lipschitzian, with L>1 strongly pseudocontractive map with T (B) bounded and F (T ). If u 1 = x 1 B, then the following assertions are equivalent: (i) Mann iteration with errors (M) converges to x F (T ). (ii) Ishikawa iteration with errors (I) converges to x F (T ).

8 Stefan M. Şoltuz Proof. The proof is similar to the proof of Theorem 4 from [15]. From (M) it follows that u n = u n+1 + α n u n α n Tu n e n Therefore =(1+α n )u n+1 + α n (I T ki)u n+1 (2 k)α n x un+1 + α n u n + α n (Tu n+1 Tu n ) e n =(1+α n )u n+1 + α n (I T ki)u n+1 (2 k)α n [(1 α n )u n + α n Tu n ]+α n u n + α n (Tu n+1 Tu n ) e n =(1+α n )u n+1 + α n (I T ki)u n+1 (1 k)α n u n +(2 k)α 2 n(u n Tu n )+α n (Tu n+1 Tu n ) e n. u n =(1+α n )u n+1 + α n (I T ki)u n+1 (3) (1 k)α n u n +(2 k)αn(u 2 n Tu n )+α n (Tu n+1 Tu n ) e n. Similarly, from (I) we obtain x n = x n+1 + α n x n α n Ty n p n =(1+α n )x n+1 + α n (I T ki)x n+1 (2 k)α n x n+1 + α n x n + α n (Tx n+1 Ty n ) p n =(1+α n )x n+1 + α n (I T ki)x n+1 (2 k)α n [(1 α n )x n + α n Ty n ]+α n x n + α n (Tx n+1 Ty n ) p n =(1+α n )x n+1 + α n (I T ki)x n+1 and therefore (1 k)α n x n +(2 k)α 2 n(x n Ty n )+α n (Tx n+1 Ty n ) p n, x n =(1+α n )x n+1 + α n (I T ki)x n+1 (4) (1 k)α n x n +(2 k)αn(x 2 n Ty n )+α n (Tx n+1 Ty n ) p n. From (3) and (4) we finally get x n u n =(1+α n )(x n+1 u n+1 ) + α n ((I T ki)x n+1 (I T ki)u n+1 ) (1 k)α n (x n u n )+(2 k)αn(x 2 n u n Ty n + Tu n ) + α n (Tx n+1 Tu n+1 Ty n + Tu n )+e n p n. (5)

Convergence of Mann iteration with errors 9 Now, (1 + α n )(x n+1 u n+1 )+α n ((I T ki)x n+1 (I T ki)u n+1 ) =(1+α n ) (x n+1 u n+1 )+ α n ((I T ki)x n+1 (I T ki)u n+1 ) 1+α n, and using (1) with x = x n+1 and y = u n+1 produces (1 + α n )(x n+1 u n+1 )+α n ((I T ki)x n+1 (I T ki)u n+1 ) (1 + α n ) x n+1 u n+1 (6) Taking norms in (5) and then using (6) yields x n u n (1 + α n )(x n+1 u n+1 ) +α n ((I T ki)x n+1 (I T ki)u n+1 ) (1 k)α n x n u n (2 k)αn 2 x n u n Ty n + Tu n α n Tx n+1 Tu n+1 Ty n + Tu n e n p n (1 + α n ) x n+1 u n+1 (1 k)α n x n u n (2 k)αn 2 x n u n Ty n + Tu n α n Tx n+1 Tu n+1 Ty n + Tu n e n p n (1 + α n ) x n+1 u n+1 (1 k)α n x n u n (2 k)αn 2 4D α n Tx n+1 Tu n+1 Ty n + Tu n e n p n, where D =diam(b,t(b)) < (recall that the sets B and T (B) are bounded). Thus the following inequality holds (1 + α n ) x n+1 u n+1 (1 + (1 k)α n ) x n u n +4D(2 k)αn 2 + + α n Tx n+1 Tu n+1 Ty n + Tu n + e n p n.

10 Stefan M. Şoltuz Finally, noting that (1 + α n ) 1 1 α n + α 2 n and (1 + α n ) 1 1 leads to x n+1 u n+1 (1 + (1 k)α n )(1 + α n ) 1 x n u n +4D(2 k)αn(1 2 + α n ) 1 + α n (1 + α n ) 1 Tx n+1 Tu n+1 Ty n + Tu n +(1+α n ) 1 e n p n (1 + (1 k)α n )(1 α n + αn) 2 x n u n +4D(2 k)αn 2 + α n Tx n+1 Tu n+1 Ty n + Tu n + e n p n (1 kα n ) x n u n +4D(2 k)αn 2 + α n Tx n+1 Tu n+1 Ty n + Tu n + e n p n. For short, x n+1 u n+1 (1 kα n ) x n u n +4D(2 k)αn 2 + + α n Tx n+1 Tu n+1 Ty n + Tu n + e n p n. (7) We now estimate Tx n+1 Tu n+1 Ty n + Tu n. (I), we get for some Lipschitzian constant L that Using (M) and Tx n+1 Tu n+1 Ty n + Tu n Tx n+1 Ty n + Tu n+1 Tu n L x n+1 y n + L u n+1 u n L (1 α n )(x n y n )+α n (Ty n y n )+p n + Lα n Tu n u n L(1 α n ) x n y n + Lα n Ty n y n + L p n + Lα n Tu n u n L β n (Tx n x n )+q n + Lα n Ty n y n + L p n + Lα n Tu n u n Lβ n Tx n x n + L q n + Lα n Ty n y n + L p n + Lα n Tu n u n 2DLβ n + L q n +2DLα n + L p n +2DLα n L[2D(β n +2α n )+ q n + p n ]. Using (7) yields x n+1 u n+1 (1 kα n ) x n u n +4D(2 k)α 2 n + α n L[2D(β n +2α n )+ q n + p n ]+ e n p n,

Convergence of Mann iteration with errors 11 or the same, x n+1 u n+1 (1 kα n ) x n u n + α n {4D(2 k)α n + L[2D(β n +2α n )+ q n + p n ]} + e n p n. Let a n := x n u n, λ n := kα n, σ n := α n {4D(2 k)α n + L[2D(β n +2α n )+ q n + p n ]}, c n := e n p n. The conditions p n < and q n < imply that lim p n = 0 and lim q n = 0, so that σ n = o(λ n ). Also c n = e n p n e n + p n <. So, from relation (2) in Lemma 2 we get lim a n =0. Hence, t lim x n u n =0. (9) Now assume that lim u n = x. Then x n x x n u n + u n x, 0, (n ). Thus, we get lim x n = x. For the converse we suppose that lim x n = x. Relation (9) and the following inequality u n x x n u n + x n x 0,(), lead us to lim u n = x. AmapS is (strongly) accretive if and only if I S) is (strongly) pseudocontractive. Using the same argumentation asi in [15] one can see that the above equivalence holds when we deal with a Lipschitz, strongly accretive and accretive map S. Cases in which we take the operators Tx = f +(x Sx) andtx = f Sx in (M) and (I). A

12 Stefan M. Şoltuz fixed point for the above T are solutions for Sx = f and x + Sx = f, with f given. The assumption that T (B) is bounded will change into (I S)(B) bounded for the strongly accretive case and S(B) bounded for the accretive case. All our results will hold in the set-valued case, if the operators admit a selection. References [1] S. S. Chang, Y. J. Cho, B. S. Lee, J.S. Jung, S. M. Kang, Iterative Approximations of Fixed Points and Solutions for Strongly Accretive and Strongly Pseudo-contractive Mappings in Banach Spaces, J. Math. Anal. Appl. 224 (1998), 149 165. [2] S. S. Chang, J. Y. Park, Y. J. Cho, Iterative Approximations of Fixed Points for Asymtotically Nonexpansive Mappings in Banach Spaces, Bull. Korean Math. Soc. 37 (2000), 109 119. [3] C. E. Chidume, Iterative Approximation of Fixed Points of Lipschitzian Strictly Pseudo-Contractive Mappings, Proc. Amer. Math. Soc. 99 (1987), 283 287. [4] C. E. Chidume, Approximation of Fixed Points of Strongly Pseudocontractive Mappings, Proc.Amer.Math.Soc.120 (1994), 546 551. [5] C. E. Chidume, C. Moore, Steepest Descent Method for Equilibrium Points of Nonlinear Systems with Accretive Operators, J. Math. Anal. Appl. 245 (2000), 142 160. [6] K. Deimling, Zeroes of Accretive Operators, Manuscripta Math. 13 (1974), 365 374. [7] S. Ishikawa, Fixed Points by a New Iteration Method, Proc. Amer. Math. Soc. 44 (1974), 147 150. [8] T. H. Kim, H. K. Xu, Some Hilbert Space Characterizations and Banach Space Inequalities, Mathematical Inequalities and Applications 1 (1998), 113-121. [9] Liwei Liu, Approximation of Fixed Points of a Strictly Pseudocontractive Mapping, Proc.Amer.Math.Soc.125 (1997), 1363 1366. [10] L.-S. Liu, Ishikawa and Mann Iterative Process with Errors for Nonlinear Strongly Accretive Mappings in Banach Spaces, J. Math. Anal. Appl. 194 (1995), 114 125. [11] W. R. Mann, Mean Value in Iteration, Proc.Amer.Math.Soc.4 (1953), 506 510. [12] S. A. Mutangadura, C. E. Chidume, An Example on the Mann Iteration Method for Lipschitz Pseudocontractions, Proc. Amer. Math. Soc. 129 (2000), 2359 2363. [13] J. A. Park, Mann-iteration for Strictly Pseudocontractive Maps, J. Korean Math. Soc. 31 (1994), 333 337.

Convergence of Mann iteration with errors 13 [14] J. Y. Park, J. Ug Jeong, Iteration Processes of Asymptotically Pseudocontractive Mappings in Banach Spaces, Bull. Korean Math. Soc. 38 (2001):3, 611 622. [15] B. E. Rhoades & Ştefan M. Şoltuz, On the Equivalence of Mann and Ishikawa Iteration Methods, International Journal of Mathematics and Mathematical Science 33: 7 (2003), 451 459. [16] X. Weng, Fixed Point Iteration for Local Strictly Pseudocontractive Mapping, Proc.Amer.Math.Soc.113 (1991), 727 731. [17] Y. Xu, Ishikawa and Mann Iterative Process with Errors for Nonlinear Strongly Accretive Operator Equations, J. Math. Anal. Appl. 224 (1998), 91 101. [18] Haiyun Zhou, Yuting Jia, Approximation of Fixed Points of Strongly Pseudocontractive Maps without Lipschitz Assumption, Proc. Amer. Math. Soc. 125 (1997), 1705 1709. (Recibido en julio de 2001; versión revisada en mayo de 2003) Ştefan M. Şoltuz, str. Avram Iancu 13 3400 Cluj-Napoca, Romania Kurt Schumacher 48, Ap. 38, 67663 Kaiserslautern, Germany e-mail: soltuz@itwm.fhg.de soltuzul@yahoo.com

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