(ProQuest: ... denotes non-US-ASCII text omitted.)
Vatan Karakaya 1 and Kadri Dogan 1 and Faik Gürsoy 2 and Müzeyyen Ertürk 2
Academic Editor:S. A. Mohiuddine
1, Department of Mathematical Engineering, Faculty of Chemistry-Metallurgical, Yildiz Technical University, Davutpasa Campus, Esenler, 34210 Istanbul, Turkey
2, Department of Mathematics, Faculty of Science and Letters, Yildiz Technical University, Davutpasa Campus, Esenler, 34220 Istanbul, Turkey
Received 2 September 2013; Accepted 14 October 2013
This is an open access article distributed under the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.
1. Introduction and Preliminaries
Most of nonlinear equations f ( x ) = y appearing in physical formulations can similarly be transformed into a fixed point equation of the form x = T x . To obtain results on existence and uniqueness of such equations' solution, an approximate fixed point theorem is applied. That is, this application will bring us to the solution of the original equation via help of a particular fixed point iteration method. For this reason, it is crucial to define a new iteration method. To decide whether an iteration method is useful for application, it is of paramount importance to answer the following questions.
(i) Does it converge to fixed point of an operator?
(ii) Is it faster than the iterations defined in the existing literature?
(iii): Is its convergence equivalent to the convergence of the other iteration methods?
(iv) Is it T -stable? and so forth.
Throughout this paper we examine four essential concepts based on the above questions for a new three-step iteration method when applied to contractive-like mapping.
As a background to our exposition, we now give some information about literature of those concepts.
The first concept of this work is about convergence of fixed point iteration methods. Fixed point iteration methods may exhibit radically different behaviors for various classes of mappings. While a particular fixed point iteration method is convergent for an appropriate class of mappings, it could not be convergent for others. Therefore, it is important to determine whether an iteration method converges to fixed point of a mapping. In this field, there are numerous works regarding convergence of various iterative methods, as one can see in [1-14].
In this work, the second concept is the rate of convergence of iteration methods. After examining convergence of an iteration method, it is important to check whether this iteration method is faster than some well-known iteration methods or not. If it is faster than some current iteration methods, then it could be more useful than the others. More details about the rate of convergence can be found in [10, 15-17].
The third concept for this work is equivalence among convergences of iteration methods. Rhoades and Soltuz [13, 18-20] showed that the convergence of Mann iteration is equivalent to Ishikawa iteration for different classes of operators. They also showed in [21] that the convergence of modified Mann iteration is equivalent to modified Ishikawa iteration under certain mappings. Afterward, Rhoades and Soltuz [14] studied that Mann and Ishikawa iteration sequences are equivalent to a multistep iteration scheme for various classes of the operators. In addition, Soltuz [22] proved that the convergence of Ishikawa iteration is equivalent to that of Mann and Picard iterations for quasicontractive operators. One can find detailed literature concerning this topic in the following list [3-5, 23-25].
The final concept in this work is stability of fixed point iteration methods. The topic of stability, as an application of the theory of fixed point, has been studied by many authors including Harder and Hicks [26, 27], Rhoades [28, 29], Osilike [30, 31], Ostrowski [32], Berinde [33], Olantiwo [9] and Singh and Prasad [34]. First stability result in metric spaces is due to Ostrowski [32], where he established the stability of Picard iteration by employing Banach's contraction condition. Afterward, several authors studied this concept in different ways.
Throughout this paper, we denote the set of natural numbers by ... . Let E be a normed space, C a nonempty convex subset of a normed space E , and T a self map of C . Let ( a n ) , ( b n ) , ( c n ) , ( α n ) , ( β n ) ⊂ [ 0,1 ] be real sequences satisfying certain conditions. Let ( x n ) ⊂ C be a sequence generated by a particular iteration process including the operator T . That is, [figure omitted; refer to PDF] where f is suitable function and x 0 ∈ C is the initial approximation. Suppose that ( x n ) converges to a fixed point x * of T . Let ( y n ) ⊂ C be an arbitrary sequence and set [figure omitted; refer to PDF] for all n ∈ ... . Then, the iteration algorithm (1) is said to be T -stable or stable with respect to T if and only if lim n [arrow right] ∞ ... n = 0 implies that lim n [arrow right] ∞ y n = p . If, in (1), [figure omitted; refer to PDF] then it is called the Picard iteration process [35].
The Mann iteration procedure given in [7] is defined by [figure omitted; refer to PDF] The sequence ( x n ) defined by [figure omitted; refer to PDF] is known as the Ishikawa iteration process [6].
The Noor iteration method [8] is defined by [figure omitted; refer to PDF] Suantai [11] proposed an iterative scheme as follows: [figure omitted; refer to PDF] Agarwal et al. established an S-iteration method in [1] as follows: [figure omitted; refer to PDF] Thianwan [12] introduced a two-step Mann iteration by [figure omitted; refer to PDF] Recently, Phuengrattana and Suantai [10] defined an SP iteration process as follows: [figure omitted; refer to PDF] Inspired by the above iteration process, we will introduce the following new iterative algorithm: [figure omitted; refer to PDF] where ( a n ) , ( b n ) , ( c n ) , ( α n ) , and ( β n ) are real sequences in [ 0,1 ] satisfying [figure omitted; refer to PDF] Some special cases of the new iteration process given in (11) are as follows.
(i) If c n = 1 and β n = α n = a n = b n = 0 for all n ∈ ... , then (11) reduces to Picard iteration (3).
(ii) If c n = β n = a n = b n = 0 for all n ∈ ... , then (11) reduces to Mann iteration (4).
(iii): If c n = β n = a n = 0 for all n ∈ ... , then (11) reduces to Ishikawa iteration (5).
(iv) If c n = b n = 0 and α n + β n = 1 for all n ∈ ... , then (11) reduces to S-iteration (8).
(v) If β n = b n = c n = 0 for all n ∈ ... , then (11) reduces to two-step Mann iteration (9).
(vi) If β n = b n = 0 for all n ∈ ... , then (11) reduces to SP iteration (10).
Quite recently, Imoru and Olatinwo [36] introduced a class of operators called contractive-like mappings by [figure omitted; refer to PDF] where δ ∈ [ 0,1 ) and [straight phi] : ... + [arrow right] ... + is a monotone increasing function with [straight phi] ( 0 ) = 0 .
In inequality (13), if we take [straight phi] ( t ) = L t , then it is reduced to the contractive definition due to Osilike and Udomene [31]. Also, by putting L = 2 δ in (13), the class of quasicontractive operators reduces to class of operators due to Berinde [2].
In [2] it was shown that the class of these operators is wider than class of Zamfirescu operators given in [37], where δ : = max { a , b / ( 1 - b ) , c / ( 1 - c ) } , δ ∈ [ 0,1 ) , and a , b , and c are real numbers satisfying 0 < a < 1 , 0 < b , and c < 1 / 2 . Besides, it is easy to see that special case of Zamfirescu operator gives Kannans' and Chatterjeas' results given in [38] and [39], respectively.
In this paper, we will prove that the new iteration method (11) is convergent to fixed point of contractive-like mappings satisfying (13). Also, by using a counterexample given in [17], we compare the rates of convergence between the new iteration method (11) and the iteration method (7) for the same class of mappings satisfying (13). Moreover, we establish an equivalence among convergences of some iteration methods including the new iteration method (11). Finally, we prove that the new iteration method (11) is T -stable.
We end this section with the following definition and lemma which will be useful in proving our main results.
Definition 1 (see [17]).
Assume that ( a n ) n ∈ ... and ( b n ) n ∈ ... are two real convergent sequences with limits a and b , respectively. Then ( a n ) n ∈ ... is said to converge faster than ( b n ) n ∈ ... if [figure omitted; refer to PDF]
Lemma 2 (see [33]).
If ρ is a real number satisfying 0 ...4; ρ < 1 and ( ξ n ) n ∈ ... is a sequence of positive numbers such that lim n [arrow right] ∞ ξ n = 0 , then for any sequence of positive numbers ( ξ n ) n ∈ ... satisfying [figure omitted; refer to PDF] one has [figure omitted; refer to PDF]
2. Main Results
Theorem 3.
Let C be a nonempty closed convex subset of an arbitrary Banach space E and T : C [arrow right] C be a mapping satisfying (13) with F T ...0; ... . Let ( x n ) a sequence defined by (11) with real sequences ( a n ) , ( b n ) , ( c n ) , ( α n ) , ( β n ) ⊂ [ 0,1 ] satisfying ( α n + β n ) n = 0 ∞ , ( a n + b n ) n = 0 ∞ ⊂ [ 0,1 ] , and ∑ n = 0 ∞ ... ( α n + β n ) = ∞ . Then the iterative sequence ( x n ) converges strongly to the fixed point of T .
Proof.
Let x * be the fixed point of T . It can be seen easily from (13) that x * is the unique fixed point of T . To show that ( x n ) converges to the fixed point x * = T x * , we use condition (13). Hence, we have [figure omitted; refer to PDF] By combining (17)-(19), we derive [figure omitted; refer to PDF] Since [straight phi] ( || x * - T x * || ) = 0 , (20) becomes [figure omitted; refer to PDF] By continuing the above processes, we obtain the following estimates [figure omitted; refer to PDF] for all n ∈ ... . Since 0 < δ < 1 , α n , β n ∈ [ 0,1 ] and ∑ n = 0 ∞ ... ( α n + β n ) = ∞ , we have [figure omitted; refer to PDF] Therefore lim n [arrow right] ∞ || x n - x * || = 0 ; that is, x n [arrow right] x * ∈ F T for all n ∈ ... .
Theorem 3 allows us to give the following example which compares the rates of convergence between the new iteration method (11) and the iteration method (7) for contractive-like operators. In the following example, for convenience, we use sequences ( v n ) and ( s n ) associated with the iterative methods (11) and (7), respectively.
Example 4 (see [17]).
Define a mapping T : [ 0,1 ] [arrow right] [ 0,1 ] as T x = x / 2 . Let α n = β n = a n = b n = c n = 0 , for n = 1,2 , ... , 24 , and α n = β n = a n = b n = 2 / n , c n = 4 / n , for all n ...5; 24 .
It can be seen easily that the mapping T satisfies condition (13) with the unique fixed point 0 ∈ F T . Furthermore, it is easy to see that Example 4 satisfies all the conditions of Theorem 3.
Indeed, let x 0 ...0; 0 be initial point for iterative methods (11) and (7). By using iterative methods (11) and (7), we have [figure omitted; refer to PDF] Now, let us compare these results as follows: [figure omitted; refer to PDF] Since [figure omitted; refer to PDF] finally we get [figure omitted; refer to PDF] Thus, from Definition 1, we conclude that the iteration method (11) is faster than the iteration method (7).
Theorem 5.
Let C be a nonempty closed convex subset of an arbitrary Banach space E and T : C [arrow right] C a mapping satisfying (13) with F T ...0; ... . If u 1 = x 1 ∈ C and α n + β n ...5; A > 0 for all n ∈ ... , then the following statements are equivalent.
(i) Mann iteration (4) converges to fixed point x * .
(ii) The new iteration (11) converges to fixed point x * .
Proof.
( i ) [implies] ( ii ) : Suppose that Mann iteration (4) converges to fixed point x * ; that is, u n [arrow right] x * as n [arrow right] ∞ . We will show that the new iteration (11) converges to the fixed point x * ; that is, x n [arrow right] x * as n [arrow right] ∞ . Using (4), (11), and (13), we have [figure omitted; refer to PDF] Substituting (32) in (31), we get [figure omitted; refer to PDF] By combining (30), (32), and (33) and using the assumption α n + β n ...5; A , we have [figure omitted; refer to PDF] Denote that [figure omitted; refer to PDF] Since lim n [arrow right] ∞ || u n - x * || = 0 and T x * = x * ∈ F T ...0; ... , it follows from (13) that lim n [arrow right] ∞ || u n - T u n || = 0 . Hence by Lemma 2 we see that [figure omitted; refer to PDF] Also, from triangle inequality we have [figure omitted; refer to PDF] and this leads to x n [arrow right] x * as n [arrow right] ∞ .
( ii ) [implies] ( i ) : Now, suppose that x n [arrow right] x * as n [arrow right] ∞ . We will show that u n [arrow right] x * as n [arrow right] ∞ . Using (4), (11), and (13), the following estimates can be obtained: [figure omitted; refer to PDF] By substituting (40) in (39), we obtain [figure omitted; refer to PDF] Again by substituting (40) and (41) in (38) and using the assumption α n + β n ...5; A , we have [figure omitted; refer to PDF] Now define [figure omitted; refer to PDF] Since x n [arrow right] x * as n [arrow right] ∞ and T x * = x * ∈ F T , it follows from (13) that [figure omitted; refer to PDF] Since the function [straight phi] is continuous, we get [figure omitted; refer to PDF] Thus Lemma 2 and (42) give || x n - u n || [arrow right] 0 as n [arrow right] ∞ .
Also, from triangle inequality we have [figure omitted; refer to PDF] and this yields u n [arrow right] x * as n [arrow right] ∞ .
With regard to ([5], Corollary 2) and Theorem 5, we can without hesitation give the following corollary.
Corollary 6.
Let C be a nonempty closed convex subset of an arbitrary Banach space E and T : C [arrow right] C a mapping satisfying (13) with F T ...0; ... . If the initial point is the same for all iterations and α n + β n ...5; A > 0 , for all n ∈ ... , then the following expressions are equivalent.
(1) The Picard iteration (1) converges to the fixed point x * of T .
(2) The Krasnoselskij iteration [40] converges to the fixed point x * of T .
(3) The Mann iteration (4) converges to the fixed point x * of T .
(4) The Ishikawa iteration (5) converges to the fixed point x * of T .
(5) The Noor iteration (6) converges to the fixed point x * of T .
(6) The S-iteration (8) converges to the fixed point x * of T .
(7) The two-step Mann iteration (9) converges to the fixed point x * of T .
(8) The SP iteration (10) converges to the fixed point x * of T .
(9) The multistep iteration [14] converges to the fixed point x * of T .
(10) The new multistep iteration [41] converges to the fixed point x * of T .
(11) The new iteration (11) converges to the fixed point x * of T .
Theorem 7.
Let ( E , || · || ) be an arbitrary Banach space, T : E [arrow right] E a self-map of E satisfying (13) with F T ...0; ... , and x * the unique fixed point of T . For x 0 ∈ E , let ( x n ) be the new iteration method defined by (11) with real sequences ( a n ) , ( b n ) , ( c n ) , ( α n ) , ( β n ) ⊂ [ 0,1 ] satisfying 0 < A ...4; α n + β n , for all n ∈ ... . Then the new iteration method (11) is T -stable.
Proof.
Let ( y n ) be an arbitrary sequence in E . Define [figure omitted; refer to PDF] for all n ∈ ... , where u n = ( 1 - a n - b n ) v n + a n T v n + b n T y n and v n = ( 1 - c n ) y n + c n T y n . Suppose that x n [arrow right] x * as n [arrow right] ∞ and lim n [arrow right] ∞ ... n = 0 . Then, we prove that lim n [arrow right] ∞ y n = x * . From condition (13), we have the following estimates: [figure omitted; refer to PDF] Substituting (49) and (50) in (48) and using the assumption α n + β n ...5; A > 0 , for all n ∈ ... , we obtain [figure omitted; refer to PDF] Thus an application of Lemma 2 to (51) yields lim n [arrow right] ∞ y n = x * .
Conversely, assume that lim n [arrow right] ∞ y n = x * . We now show that lim n [arrow right] ∞ [varepsilon] n = 0 . From condition (13) and triangle inequality we have [figure omitted; refer to PDF] Since δ ∈ [ 0,1 ) and α n + β n ∈ [ 0,1 ] , for all n ∈ ... , [figure omitted; refer to PDF] By taking the limit as n [arrow right] ∞ of both sides of (52) and using the assumption lim n [arrow right] ∞ || y n - x * || = 0 , we have lim n [arrow right] ∞ [varepsilon] n = 0 .
Conflict of Interests
The authors declare that there is no conflict of interests regarding the publication of this paper.
[1] R. P. Agarwal, O. O'Regan, D. R. Sahu, "Iterative construction of fixed points of nearly asymptotically non expansive mappings," Journal of Nonlinear and Convex Analysis , vol. 8, no. 1, pp. 6179-6189, 2007.
[2] V. Berinde, "On the convergence of the Ishikawa iteration in the class of quasi contractive operators," Acta Mathematica Universitatis Comenianae , vol. 73, no. 1, pp. 119-126, 2004.
[3] R. Chugh, V. Kumar, "Strong convergence of SP iterative scheme for Quasi-contractive operators," International Journal of Computer Applications , vol. 31, no. 5, pp. 21-27, 2011.
[4] R. Chugh, V. Kumar, S. Kumar, "Strong convergence of a new three step iterative scheme in Banach space," American Journal of Computational Mathematics , vol. 2, pp. 345-357, 2012.
[5] F. Gürsoy, V. Karakaya, B. E. Rhoades, "The equivalence among new multistep iteration, S-iteration and some other iterative schemes," http://arxiv.org/pdf/1211.5701.pdf
[6] S. Ishikawa, "Fixed points by a new iteration method," Proceedings of the American Mathematical Society , vol. 44, pp. 147-150, 1974.
[7] W. R. Mann, "Mean value methods in iterations," Proceedings of the American Mathematical Society , vol. 4, pp. 506-510, 1953.
[8] M. A. Noor, "New approximation schemes for general variational inequalities," Journal of Mathematical Analysis and Applications , vol. 251, no. 1, pp. 217-229, 2000.
[9] M. Olantiwo, "Some stability and strong convergence results for the Jungck-Ishikawa iteration process," Creative Mathematics and Informatics , vol. 17, pp. 33-42, 2008.
[10] W. Phuengrattana, S. Suantai, "On the rate of convergence of Mann, Ishikawa, Noor and SP-iterations for continuous functions on an arbitrary interval," Journal of Computational and Applied Mathematics , vol. 235, no. 9, pp. 3006-3014, 2011.
[11] S. Suantai, "Weak and strong convergence criteria of Noor iterations for asymptotically nonexpansive mappings," Journal of Mathematical Analysis and Applications , vol. 311, no. 2, pp. 506-517, 2005.
[12] S. Thianwan, "Common fixed points of new iterations for two asymptotically nonexpansive nonself-mappings in a Banach space," Journal of Computational and Applied Mathematics , vol. 224, no. 2, pp. 688-695, 2009.
[13] B. E. Rhoades, S. M. Soltuz, "On the equivalence of Mann and Ishikawa iteration methods," International Journal of Mathematics and Mathematical Sciences , vol. 2003, no. 7, pp. 451-459, 2003.
[14] B. E. Rhoades, S. M. Soltuz, "The equivalence between Mann-Ishikawa iterations and multistep iteration," Nonlinear Analysis, Theory, Methods and Applications , vol. 58, no. 1-2, pp. 219-228, 2004.
[15] V. Berinde, "Picard iteration converges faster than Mann iteration for a class of quasi-contractive operators," Fixed Point Theory and Applications , vol. 2004, no. 2, pp. 97-105, 2004.
[16] N. Hussain, A. Rafiq, B. Damjanovic, R. Lazovic, "On rate of convergence of various iterative schemes," Fixed Point Theory and Applications , vol. 2011, pp. 45, 2011.
[17] Y. Qing, B. E. Rhoades, "Comments on the rate of convergence between mann and ishikawa iterations applied to zamfirescu operators," Fixed Point Theory and Applications , vol. 2008, 2008.
[18] B. E. Rhoades, S. M. Soltuz, "The equivalence of mann iteration and ishikawa iteration for non-lipschitzian operators," International Journal of Mathematics and Mathematical Sciences , vol. 2003, no. 42, pp. 2645-2651, 2003.
[19] B. E. Rhoades, S. M. Soltuz, "The equivalence between the convergences of Ishikawa and Mann iterations for an asymptotically pseudocontractive map," Journal of Mathematical Analysis and Applications , vol. 283, no. 2, pp. 681-688, 2003.
[20] B. E. Rhoades, S. M. Soltuz, "The equivalence between the Mann and Ishikawa iterations dealing with generalized contractions," International Journal of Mathematics and Mathematical Sciences , vol. 2006, 2006.
[21] B. E. Rhoades, S. M. Soltuz, "The equivalence between the convergences of Ishikawa and Mann iterations for an asymptotically nonexpansive in the intermediate sense and strongly successively pseudocontractive maps," Journal of Mathematical Analysis and Applications , vol. 289, no. 1, pp. 266-278, 2004.
[22] S. M. Soltuz, "The equivalence of Picard, Mann, and Ishikawa iterations dealing with quasi- contractive operators," Mathematical Communications , vol. 10, pp. 81-89, 2005.
[23] A. Rafiq, "On the equivalence of Mann and Ishikawa iteration methodes with errors," Mathematical Communications , vol. 11, pp. 143-152, 2006.
[24] S. M. Soltuz, "The equivalence between Krasnoselkij, Mann, Ishikawa, Noor and multistep iteration," Mathematical Communications , vol. 12, pp. 53-61, 2007.
[25] X. Zhiqun, "Remarks of equivalence among Picard, Mann, and Ishikawa Iterations in normed spaces," Fixed Point Theory and Applications , vol. 2007, 2007.
[26] A. M. Harder, T. L. Hicks, "Stability results for fixed point iteration procedures," Mathematica Japonica , vol. 33, pp. 693-706, 1988.
[27] A. M. Harder, T. L. Hicks, "A stable iteration procedure for nonexpansive mappings," Mathematica Japonica , vol. 33, pp. 687-692, 1988.
[28] B. E. Rhoades, "Fixed point theorems and stability results for fixed point iteration procedures," Indian Journal of Pure and Applied Mathematics , vol. 21, no. 1, pp. 1-9, 1990.
[29] B. E. Rhoades, "Fixed point theorems and stability results for fixed point iteration procedures. II," Indian Journal of Pure and Applied Mathematics , vol. 24, no. 11, pp. 691-703, 1993.
[30] M. O. Osilike, "Stability results for fixed point iteration procedures," Journal of Nigerian Mathematical Society , vol. 26, no. 10, pp. 937-945, 1995.
[31] M. O. Osilike, A. Udomene, "Short proofs of stability results for fixed point iteration procedures for a class of contractive-type mappings," Indian Journal of Pure and Applied Mathematics , vol. 30, no. 12, pp. 1229-1234, 1999.
[32] M. Ostrowski, "The round-off stability of iterations," Zeitschrift für Angewandte Mathematik und Mechanik , vol. 47, no. 2, pp. 77-81, 1967.
[33] V. Berinde Iterative Approximation of Fixed Points , Springer, Berlin, Germany, 2007.
[34] S. L. Singh, B. Prasad, "Some coincidence theorems and stability of iterative procedures," Computers and Mathematics with Applications , vol. 55, no. 11, pp. 2512-2520, 2008.
[35] E. Picard, "Memoire sur la theorie des equations aux derivees partielles et la methode des approximations successives," Journal de Mathématiques Pures et Appliquées , vol. 6, pp. 145-210, 1890.
[36] C. O. Imoru, M. O. Olatinwo, "On the stability of Picard and Mann iteration processes," Carpathian Journal of Mathematics , vol. 19, no. 2, pp. 155-160, 2003.
[37] T. Zamfirescu, "Fix point theorems in metric spaces," Archiv der Mathematik , vol. 23, no. 1, pp. 292-298, 1972.
[38] R. Kannan, "Some results on fixed points," Bulletin of Calcutta Mathematical Society , vol. 10, pp. 71-76, 1968.
[39] S. K. Chatterjea, "Fixed point theorems," Comptes Rendus de l'Academie Bulgare des Sciences , vol. 25, pp. 727-730, 1972.
[40] H. Schaefer, "Uber die methode sukzessiver approximationen," Jahresbericht-Deutsche Mathematiker-Vereinigung , vol. 59, pp. 131-140, 1957.
[41] F. Gürsoy, V. Karakaya, B. E. Rhoades, "Data dependence results of new multistep and S-iterative schemes for contractive-like operators," Fixed Point Theory and Applications , vol. 2013, pp. 76, 2013.
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Abstract
We introduce a new three-step iteration scheme and prove that this new iteration scheme is convergent to fixed points of contractive-like operators. Also, by providing an example, we show that our new iteration method is faster than another iteration method due to Suantai (2005). Furthermore, it is shown that this new iteration method is equivalent to some other iteration methods in the sense of convergence. Finally, it is proved that this new iteration method is T -stable.
You have requested "on-the-fly" machine translation of selected content from our databases. This functionality is provided solely for your convenience and is in no way intended to replace human translation. Show full disclaimer
Neither ProQuest nor its licensors make any representations or warranties with respect to the translations. The translations are automatically generated "AS IS" and "AS AVAILABLE" and are not retained in our systems. PROQUEST AND ITS LICENSORS SPECIFICALLY DISCLAIM ANY AND ALL EXPRESS OR IMPLIED WARRANTIES, INCLUDING WITHOUT LIMITATION, ANY WARRANTIES FOR AVAILABILITY, ACCURACY, TIMELINESS, COMPLETENESS, NON-INFRINGMENT, MERCHANTABILITY OR FITNESS FOR A PARTICULAR PURPOSE. Your use of the translations is subject to all use restrictions contained in your Electronic Products License Agreement and by using the translation functionality you agree to forgo any and all claims against ProQuest or its licensors for your use of the translation functionality and any output derived there from. Hide full disclaimer