A Classes of Variational Inequality Problems Involving Multivalued Mappings

Science Journal of Applied Mathematics and Statistics 2018; 6(1): 43-48 http://www.sciencepublishinggroup.com/j/sjams doi: 10.11648/j.sjams.20180601.15 ISSN: 2376-9491 (Print); ISSN: 2376-9513 (Online) A Classes of Variational Inequality Problems Involving Multivalued Mappings Nedal Hassan Elbadowi Eljaneid Department of Mathematics, Faculty of Sciences, University of Tabuk, Tabuk, Kingdom of Saudi Arabia Email address: To cite this article: Nedal Hassan Elbadowi Eljaneid. A Classes of Variational Inequality Problems Involving Multivalued Mappings. Science Journal of Applied Mathematics and Statistics. Vol. 6, No. 1, 2018, pp. 43-48. doi: 10.11648/j.sjams.20180601.15 Received: January 5, 2018; Accepted: January 17, 2018; Published: February 24, 2018 Abstract: The main objective of the Variational inequality problem is to study some functional analytic tools, projection method and fixed point theorems and then exploiting these to study the existence of solutions and convergence analysis of iterative algorithms developed for some classes of Variational inequality problem. The main objective of this paper is to study the existence of solutions of some classes of Variational inequalities using fixed point theorems for multivalued and using Banach contraction theorem we prove the existence of a unique solution of multi value Variational inequality problem. Keywords: Fixed Points Theorems, Variational Inequality Problems, Strongly Lipschitz Operator 1. Introduction Variational inequalities and complementarity problem play equally important roles in applied mathematics, physics, control theory and optimization, equilibrium theory of transportation and economics, mechanics, and engineering sciences. We study the existence and convergence of solutions of some classes of Variational inequalities using fixed point theorem for multivalued mappings we develop an iterative algorithm for prove the approximate solution converges to solution of multi value Variational inequality problem. Definition (1-1): Let be a metric space with metric. A mapping : is called contraction mapping if:,,,, Definition (1-2): Let.,. : be a bilinear from, a nonempty closed convex set of. Definition (1-2): If and project any point, on the axis then the projection,0. Theorem (1-3): Let be a real Hilbert space, let be a nonempty closed convex set and let due the projection mapping on. Then is non expansive, monotone, but not strictly monotone and strongly continuous. Proof: Let us first note that the characterization of the projection #$,#$% 0, # can be written $, $# # (1) To show that is monotone, let us fix & '& and write $, $# # (2) $, $# # (3) Putting # in 1.2 & # '& 1, we have $ $ *, $ 0 (4) And therefore $ $, $, (5) Which in particular implies the monotonicity of P -, further if KH then P - 1, an identity mapping, and one has strict monotonicity, but in general for K0H then is not injective and hence not strictly monotone, If then

44 Nedal Hassan Elbadowi Eljaneid: A Classes of Variational Inequality Problems Involving Multivalued Mappings 00 but =. To show that P - is non expansive it is enough to apply the Schwartz inequality to (1.5) and obtain thus (6) Or, dividing by =0 then. the strong continuity follows immediately form (5). 2. Preliminaries Definition (2-1): Let be a real Hilbert space and. &.,. denote norm and inner product on respectively. Given multivalued mappings 4,5: 2 6 is a power set of, a nonlinear mapping 7: and a proper convex and lower. Semi continuous function 8: { + } with =>7 > @8 A, where @8 denote the subdifferential of 8. We consider the following Variational inequality problem (GVIP): GVIP: Find B, 4B,# 5B such that 7B > @8 A and #,C 7B 87B 8C, C. Definition (2-2): let 7: is said to be: ' C FG&7# >&G&H, if there exists a constant C>0 such that 7B 7C,B C C B C, B,C '' J K'LFMh'GO continuous, if there exists a constant J>0 such that 7B 7C J B C, B,C Definition (2-3): A multivalued mapping 4: 2 6 is said to be: ' FG&7# >&G&H, if there exists a constant >0 such that #,B C B C, B,C, 4B & # 4C '' J % K'LFMh'GO continuous, if there exists a constant J>0 such that J 4B,4C % B C, B,C PhHH % 5,Q =sup { : 5, Q} &# 5,Q 2 6 Definition (2-4): KHG, H >HG'M FLMH & 4: H >LL'&7. A point is said to be fixed point 4 if =. Fixed Point Problem: Let 4 be a mapping defined on a metric space, into itself, find such that 4=. Definition (2-5): If is multivalued mapping on into itself. Then a point is called a fixed point of if. Lemma (2-6): A mutivalued mapping & '&G U is continuous at point V if and only if W V for all sequence { W } '& P'Gh W V Proof: Suppose that W V. Given X>0 there exists Y >0 such that And there exists a positive integer \ such that Thus, if & \ we have V <Y B C <X B V & C Therefore W. Conversely, suppose that W,'.H ' & \ V W <Y & \ B W B <X B W W & B B W B <X B W W & B And W <Y. Suppose that is not continuous at V. Then there exists >0, for each Y >0 there exists such that V <Y B C <X B V & C In particular, for each positive integer & there exists W such that V < 1 & & B W B V <X B W W & B V V Clearly, W converges to but W does not converges to V. which is a contradiction, this prove the lemma #

Science Journal of Applied Mathematics and Statistics 2018; 6(1): 43-48 45 Theorem (2-7): KHG H Q&Mh FLMH. If is multivalued contraction mapping on into itself Then has a fixed point. L: KHG ] <1 be contraction constant for and let V. Choose V. Since V & are subsets of and V there is a such that ] V. Now, since & are subsets of and, there is a point ^ such that ^ ] ] V We product a sequence { W } of points of such that W_ W & Now W W_ ] W` W ] V, & 1 W W_a W W_ W_ W_ + + W_a` W_a ] W V +] W_ V +..+] W_a` V = ] W +] W_ + +] W_a` V f ] W cd] e h V &,> 1 egv = ]W 1 ] V &,> 1 = &,>, then the sequence { W } is a Cauchy sequence. Since is Banach space Lemma (2-8) : B, 4B,# 5B is a solution of GVIP if and only if for some given >0, the mapping : 2 6 defined by B = i i jb 7B +L k l 7B # m q rp n op Has a fixed point B, where L k l ==+@8 ` is called proximal mapping. = stands for the identity mapping on. Proof: Let B, 4B,# 5B be a solution of GVIP,'.H.B, 4B,# 5B satisfy #,C 7B 8 7B 8C, C. By definition of @8 we have #, 7B 7B # 7B +@8 7B 7B # =+ @8 7B L k l 7B # =7B B=B 7B +L k l 7B # i i jb 7B +L k l 7B # m q rp n op B B Conversely, let B be a fixed point of,'.h. 4B,# 5B such that B=B 7B +L k l 7B # 7B = L k l 7B # 7B # =+ @8 7B 7B # 7B +@8 7B # @8 7B

46 Nedal Hassan Elbadowi Eljaneid: A Classes of Variational Inequality Problems Involving Multivalued Mappings # @8 7B,F'&MH >0 Hence, by definition of @8 #,C 7B 8 7B 8C, C. This complete the proof # 3. Main Result Let 4,5: 2 6 be multivalued mappings then multivalued Variational inequality problem is to find B such that L,C B t,c B, C & L 4B,t 5B (7) Let 4 & 5 are nonlinear mappings on into, the single value Variational inequality problem is to find B such that : 4B,C B 5B,C B, C (8) Lemma (3-1): B,L,t P'Gh B,L 4B,t 5B, is a solution of multivalued Variational inequality problem (3-1) if and only if B is a fixed point of mapping : 2 6 defined as B = i C ul t v rp w op For some positive u. Proof : Suppose B,L,t satisfies if it satisfies L t,c B 0, C Or B B ul t,c B C B 0, C If and only, the Theorem (2-3) B,L,t satisfies B= C ul t Or B B = v rp C ul t w op We prove the existence of a unique solution of multivalued Variational inequality problem (3-1) Theorem (3-2): Let 4: 2 6 be a % Lipschitz continuous and x -strongly monotone multivalued mapping and let 5: 2 6 be J Lipschitz continuous multivalued mapping. then multivalued Variational inequality problem (3-1) has a solution. Proof: By Lemma (3-1), it is enough to prove that multivalued mapping is contraction mapping. Let P B & P B, we have P = B ul t L 4B & t 5C P = B ul t L 4B & t 5C Now P P =y B ul t B ul t y yb ul t B +ul t y B B ul L +u t t B B ul L +u J t t By x -strongly monotonicity and % Lipschitz continuous of 4, we have B B ul L B B 2uL L,B B +u L L B B 2ux B B +u % B B 1 2ux +u % B B Therefore: P P z 1 2ux +u % B B +u J B B Where {= u J + 1 2ux +u % <1 = u J + z 1 2ux +u % B B = { B B

Science Journal of Applied Mathematics and Statistics 2018; 6(1): 43-48 47 u< 2x J % J, J <x & J <x Hence is contraction multivalued mapping. By Theorem (3-2), has a fixed point, say B,'.H,B B then B= B ul t & L 4B,t 5B This completes the proof # Iterative Algorithm (3-3): For any given B V, compute B W_ defined as B W_ = B W ul W t W 9 L W_ 4B W_ & t W_ 5B W_ F>H M&FG&G u Theorem (3-4): Let 4: 2 6 be a % Lipschitz continuous and x -strongly monotonicity multivalued mapping and let 5: 2 6 be J Lipschitz continuous multivalued mapping. If B W_,L W_,t W_ & B,L,t are solution of (7) and (8) respectively then B W_ converges strongly to B '&,L W_ converges strongly to L '& & t W_ converges strongly to t '& u< 2x J J %, J >x & J >x Proof: By Lemma (3-1) and Iterative Algorithm (3-4), we have B W_ B= B W ul W t W B ul t Therefore, B W_ B =y B W ul W t W B ul t y ~u J + z 1 2ux +u % B B = { B B By theorem Where {= u J + 1 2ux +u % <1 For u< ƒ` ƒ ƒ ` ƒ, J <x & J <x Then by iteration, we have B W_ B { W B B Since {<1. we have B W_ converges to B strongly in, we have L W_ L strongly in and t W_ t strongly in. This completes the proof # 4. Conclusions We study the existence of solutions of some classes of Variational inequalities using fixed point theorems for multivalued and using Banach contraction theorem we prove the existence of a unique solution of multi value Variational inequality problem discussed in the article research. Acknowledgements I would like to express my thanks to an anonymous referee for useful comments. Statement of the Problem Find solutions of some classes of Variational inequalities. Research Objectives Study the existence of solutions of some classes of Variational inequalities using fixed point theorems for multivalued and using Banach contraction theorem References [1] Baiocchi, C. and Capelo, A. Variational and qualities, Applications to free boundary problem, John Wiley and Sons, New York 1984. [2] Cottle, R. W. Giannessi, F. and Lions, J. L, Variational inequalities and complementarity problems, Theory and applications, John Wiley and Sons, New York. [3] Duvaut, G, and Lions, J. L. Inequalities in mechanics and physics, Springer Verlag, Berlin, 1976. [4] Eilenberg S. and Montgomery D. Fixed point theorem for multivalued transformations, Amer. J. Math (1946). [5] Ekland, I, and Temam, R,. Convex analysis and Variational inequalities, North Holland, Amsterdam, 1976. [6] Hlavacak, I, Haslinger, J, and Necas. J., Solutions of Variational inequalities in mechanics, Springer Verlag, New York, 1988. [7] Khalil Ahmad, K. R. Kazmi and Z. A. Siddiqui, On a class of Generalized Variational Inequalities, Indian. J. Pure app. Math 28 (4): 487-499. April 1997. [8] Mircea, S. and Analuzia, M, Variational inequalities with applications, study of antiplane frictional contact problems, Springer. [9] Ram U. Verma, Generalized nonlinear Variational inequality problems involving Multivalued Mappings, Journal of Applied Mathematics and Stochastic Analysis, (1997), 289-295.

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