A-monotonicity and applications to nonlinear variational inclusion...
Transcript of A-monotonicity and applications to nonlinear variational inclusion...
A-MONOTONICITY AND APPLICATIONS TO NONLINEARVARIATIONAL INCLUSION PROBLEMS
RAM U. VERMA
Received 2 March 2004
A new notion of the A-monotonicity is introduced, which generalizes the H-monoto-nicity. Since the A-monotonicity originates from hemivariational inequalities, and hemi-variational inequalities are connected with nonconvex energy functions, it turns out tobe a useful tool proving the existence of solutions of nonconvex constrained problems aswell.
Recently, Fang and Huang [1] introduced a new class of mappings—h-monotonemappings—in the context of solving a system of variational inclusions involving a com-bination of h-monotone and strongly monotone mappings based on the resolvent oper-ator technique. The notion of the h-monotonicity has revitalized the theory of maximalmonotone mappings in several directions, especially in the domain of applications. Herewe announce the notion of the A-monotone mappings and its applications to the solvabil-ity of systems of nonlinear variational inclusions. The class of the A-monotone mappingsgeneralizes the h-monotonicity. On the top of that, A-monotonicity originates from hemi-variational inequalities, and emerges as a major contributor to the solvability of nonlinearvariational problems on nonconvex settings. As a matter of fact, some nice examples onA-monotone (or generalized maximal monotone) mappings can be found in Naniewiczand Panagiotopoulos [2] and Verma [4]. Hemivariational inequalities—initiated and de-veloped by Panagiotopoulos [3]—are connected with nonconvex energy functions andturned out to be useful tools proving the existence of solutions of nonconvex constrainedproblems. We note that the A-monotonicity is defined in terms of relaxed monotonemappings—a more general notion than the monotonicity/strong monotonicity—whichgives a significant edge over the h-monotonicity.
Definition 1 [1]. Let h : H →H and M : H → 2H be any two mappings on H . The map Mis said to be h-monotone if M is monotone and (h+ ρM)(H)=H holds for ρ > 0. This isequivalent to stating that M is h-monotone if M is monotone and (h+ ρM) is maximalmonotone.
Copyright © 2004 Hindawi Publishing CorporationJournal of Applied Mathematics and Stochastic Analysis 2004:2 (2004) 193–1952000 Mathematics Subject Classification: 49J40, 47J20URL: http://dx.doi.org/10.1155/S1048953304403013
194 Variational inclusion problems
Let X denote a reflexive Banach space and X∗ its dual. Inspired by [2, 4], we introducethe notion of the A-monotonicity as follows.
Definition 2. Let A : X → X∗ and M : X → 2X∗
be any mappings on X . The map M is saidto be A-monotone if M is m-relaxed monotone and (A+ ρM) is maximal monotone forρ > 0.
Lemma 3. Let A : H →H be r-strongly monotone and M : H → 2H be A-monotone. Thenthe resolvent operator J
ρA,M : H →H is (1/(r− ρm))-Lipschitz continuous for 0 < ρ < r/m.
Example 4 [2, Lemma 7.11]. Let A : X → X∗ be (m)-strongly monotone and f : X → R belocally Lipschitz such that ∂ f is (α)-relaxed monotone. Then ∂ f is A-monotone, that is,A+ ∂ f is maximal monotone for m−α > 0, where m,α > 0.
Example 5 [4, Theorem 4.1]. Let A : X → X∗ be (m)-strongly monotone and let B : X →X∗ be (c)-strongly Lipschitz continuous. Let f : X → R be locally Lipschitz such that ∂ fis (α)-relaxed monotone. Then ∂ f is (A−B)-monotone.
Let H1 and H2 be two real Hilbert spaces and K1 and K2, respectively, be nonemptyclosed convex subsets of H1 and H2. Let A : H1 → H1, B : H2 → H2, M : H1 → 2H1 , andN : H2 → 2H2 be nonlinear mappings. Let S : H1×H2 →H1 and T : H1×H2 →H2 be anytwo multivalued mappings. Then the problem of finding (a,b)∈H1×H2 such that
0∈ S(a,b) +M(a), 0∈ T(a,b) +N(b) (1)
is called the system of nonlinear variational inclusion (SNVI) problems.When M(x)= ∂K1 (x) and N(y)= ∂K2 (y) for all x ∈ K1 and y ∈ K2, where K1 and K2,
respectively, are nonempty closed convex subsets of H1 and H2, and ∂K1 and ∂K2 denoteindicator functions of K1 and K2, respectively, the SNVI (1) reduces to determine anelement (a,b)∈ K1×K2 such that
⟨S(a,b),x− a
⟩≥ 0 ∀x ∈ K1, (2)⟨T(a,b), y− b
⟩≥ 0 ∀y ∈ K2. (3)
Lemma 6. Let H1 and H2 be two real Hilbert spaces. Let A : H1 →H1 and B : H2 →H2 bestrictly monotone, let M : H1 → 2H1 be A-monotone, and let N : H2 → 2H2 be B-monotone.Let S : H1 ×H2 → H1 and T : H1 ×H2 → H2 be any two multivalued mappings. Then agiven element (a,b) ∈ H1 ×H2 is a solution to the SNVI (1) problem if and only if (a,b)satisfies
a= JρA,M
(A(a)− ρS(a,b)
), b = J
ηB,N
(B(b)−ηT(a,b)
). (4)
Theorem 7. Let H1 and H2 be two real Hilbert spaces. Let A : H1 → H1 be (r1)-stronglymonotone and (α1)-Lipschitz continuous, and let B : H2 → H2 be (r2)-strongly monotoneand (α2)-Lipschitz continuous. Let M : H1 → 2H1 be A-monotone and let N : H2 → 2H2 beB-monotone. Let S : H1×H2 →H1 be such that S(·, y) is (γ,r)-relaxed cocoercive and (µ)-Lipschitz continuous in the first variable and S(x,·) is (ν)-Lipschitz continuous in the secondvariable for all (x, y)∈H1×H2. Let T : H1×H2 →H2 be such that T(u,·) is (λ,s)-relaxed
Ram U. Verma 195
cocoercive and (β)-Lipschitz continuous in the second variable and T(·,v) is (τ)-Lipschitzcontinuous in the first variable for all (u,v) ∈ H1 ×H2. If, in addition, there exist positiveconstants ρ and η such that
√α1− 2ρr + 2ργµ2 + ρ2µ2 +ητ < r1,√α2− 2ηs+ 2ηλβ2 +η2β2 + ρν < r2,
(5)
then the SNVI (1) problem has a unique solution.
References
[1] Y. P. Fang and N. J. Huang, H-monotone operators and system of variational inclusions, Comm.Appl. Nonlinear Anal. 11 (2004), no. 1, 93–101.
[2] Z. Naniewicz and P. D. Panagiotopoulos, Mathematical Theory of Hemivariational Inequalitiesand Applications, Monographs and Textbooks in Pure and Applied Mathematics, vol. 188,Marcel Dekker, New York, 1995.
[3] P. D. Panagiotopoulos, Hemivariational Inequalities. Applications in Mechanics and Engineering,Springer-Verlag, Berlin, 1993.
[4] R. U. Verma, Nonlinear variational and constrained hemivariational inequalities involving re-laxed operators, ZAMM Z. Angew. Math. Mech. 77 (1997), no. 5, 387–391.
Ram U. Verma: International Publications, 5066 Jamieson Drive, Suite B-9, Toledo, OH 43613,USA
E-mail address: [email protected]
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