(ProQuest: ... denotes non-US-ASCII text omitted.)

Ming-ge Yang 1, 3 and Jiu-ping Xu 2 and Nan-jing Huang 1, 2

Recommended by Yeol J. E. Cho

1, Department of Mathematics, Sichuan University, Chengdu, Sichuan 610064, China
2, College of Business and Management, Sichuan University, Chengdu, Sichuan 610064, China
3, Department of Mathematics, Luoyang Normal University, Luoyang, Henan 471022, China

Received 27 September 2010; Accepted 22 October 2010

1. Introduction

In 1979, Robinson [1] studied the following parametric variational inclusion problem: given x∈^...n , find y∈^...m such that [figure omitted; refer to PDF] where g:^...n ×^...m [arrow right]^...p is a single-valued function and Q:^...n ×^...m ...^...p is a multivalued map. It is known that (1.1) covers variational inequality problems and a vast of variational system important in applications. Since then, various types of variational inclusion problems have been extended and generalized by many authors (see, e.g., [2-7] and the references therein).

On the other hand, Tarafdar [8] generalized the classical Himmelberg fixed point theorem [9] to locally H -convex uniform spaces (or LC -spaces). Park [10] generalized the result of Tarafdar [8] to locally G -convex spaces (or LG -spaces). Recently, Park [11] introduced the concept of abstract convex spaces which include H -spaces and G -convex spaces as special cases. With this new concept, he can study the KKM theory and its applications in abstract convex spaces. More recently, Park [12] introduced the concept of LΓ -spaces which include LC -spaces and LG -spaces as special cases. He also established the Himmelberg type fixed point theorem in LΓ -spaces. To see some related works, we refer to [13-21] and the references therein. However, to the best of our knowledge, there is no paper dealing with systems of generalized quasivariational inclusion problems in LΓ -spaces.

Motivated and inspired by the works mentioned above, in this paper, we first prove that the product of a family of LΓ -spaces is also an LΓ -space. Then, by using the Himmelberg type fixed point theorem due to Park [12], we establish existence theorems of solutions for systems of generalized quasivariational inclusion problems, systems of variational equations, and systems of generalized quasiequilibrium problems in LΓ -spaces. Applications of the existence theorem of solutions for systems of generalized quasiequilibrium problems to optimization problems are given in LΓ -spaces.

2. Preliminaries

For a set X , ...X... will denote the family of all nonempty finite subsets of X . If A is a subset of a topological space, we denote by intA and A¯ the interior and closure of A , respectively.

A multimap (or simply a map) T:X...Y is a function from a set X into the power set ^2Y of Y ; that is, a function with the values T(x)⊂Y for all x∈X . Given a map T:X...Y , the map ^T- :Y...X defined by ^T- (y)={x∈X:y∈T(x)} for all y∈Y , is called the (lower) inverse of T . For any A⊂X , T(A):=_...x∈A T(x) . For any B⊂Y , ^T- (B):={x∈X:T(x)∩B≠∅} . As usual, the set {(x,y)∈X×Y:y∈T(x)}⊂X×Y is called the graph of T .

For topological spaces X and Y , a map T:X...Y is called

(i) closed if its graph Graph(T) is a closed subset of X×Y ,

(ii) upper semicontinuous (in short, u.s.c.) if for any x∈X and any open set V in Y with T(x)⊂V , there exists a neighborhood U of x such that T(x')⊂V for all x'∈U ,

(iii): lower semicontinuous (in short, l.s.c.) if for any x∈X and any open set V in Y with T(x)∩V≠∅ , there exists a neighborhood U of x such that T(x')∩V≠∅ for all x'∈U ,

(iv) continuous if T is both u.s.c. and l.s.c.,

(v) compact if T(X) is contained in a compact subset of Y .

Lemma 2.1 . (see [22]).

Let X and Y be topological spaces, T:X...Y be a map. Then, T is l.s.c. at x∈X if and only if for any y∈T(x) and for any net {_xα } in X converging to x , there exists a net {_yα } in Y such that _yα ∈T(_xα ) for each α and _yα converges to y .

Lemma 2.2 . (see [23]).

Let X and Y be Hausdorff topological spaces and T:X...Y be a map.

(i) If T is an u.s.c. map with closed values, then T is closed.

(ii) If Y is a compact space and T is closed, then T is u.s.c.

(iii): If X is compact and T is an u.s.c. map with compact values, then T(X) is compact.

In what follows, we introduce the concept of abstract convex spaces and map classes [real] , [real]... and [real]... having certain KKM properties. For more details and discussions, we refer the reader to [11, 12, 24].

Definition 2.3 (see [11]).

An abstract convex space (E,D;Γ) consists of a topological space E , a nonempty set D , and a map Γ:...D......E with nonempty values. We denote _ΓA :=Γ(A) for A∈...D... .

In the case E=D , let (E;Γ):=(E,E;Γ) . It is obvious that any vector space E is an abstract convex space with Γ=co , where co denotes the convex hull in vector spaces. In particular, (...;co ) is an abstract convex space.

Let (E,D;Γ) be an abstract convex space. For any D'⊂D , the Γ -convex hull of D' is denoted and defined by [figure omitted; refer to PDF] (co is reserved for the convex hull in vector spaces). A subset X of E is called a Γ -convex subset of (E,D;Γ) relative to D' if for any N∈...D'... , we have _ΓN ⊂X ; that is, co_Γ D'⊂X . This means that (X,D';Γ_|...D'... ) itself is an abstract convex space called a subspace of (E,D;Γ) . When D⊂E , the space is denoted by (E⊃D;Γ) . In such case, a subset X of E is said to be Γ -convex if co_Γ (X∩D)⊂X ; in other words, X is Γ -convex relative to D'=X∩D . When (E;Γ)=(...;co ) , Γ -convex subsets reduce to ordinary convex subsets.

Let (E,D;Γ) be an abstract convex space and Z a set. For a map F:E...Z with nonempty values, if a map G:D...Z satisfies [figure omitted; refer to PDF] then G is called a KKM map with respect to F . A KKM map G:D...E is a KKM map with respect to the identity map _1E . A map F:E...Z is said to have the KKM property and called a [real] -map if, for any KKM map G:D...Z with respect to F , the family {G(y)_}y∈D has the finite intersection property. We denote [figure omitted; refer to PDF]

Similarly, when Z is a topological space, a [real]... -map is defined for closed-valued maps G , and a [real]... -map is defined for open-valued maps G . In this case, we have [figure omitted; refer to PDF] Note that if Z is discrete, then three classes [real] , [real]... and [real]... are identical. Some authors use the notation KKM(E,Z) instead of [real]...(E,Z) .

Definition 2.4 . (see [24]).

For an abstract convex space (E,D;Γ) , the KKM principle is the statement _1E ∈[real]...(E,E)∩[real]...(E,E) .

A KKM space is an abstract convex space satisfying the KKM principle.

Definition 2.5.

Let (Y;Γ) be an abstract convex space, Z be a real t.v.s., and F:Y...Z a map. Then,

(i) : F is {0} -quasiconvex-like if for any {_y1 ,_y2 ,...,_yn }∈...Y... and any y¯∈Γ({_y1 ,_y2 ,...,_yn }) there exists j∈{1,2,...,n} such that F(y¯)⊂F(_yj ) ,

(ii) : F is {0} -quasiconvex if for any {_y1 ,_y2 ,...,_yn }∈...Y... and any y¯∈Γ({_y1 ,_y2 ,...,_yn }) there exists j∈{1,2,...,n} such that F(_yj )⊂F(y¯) .

Remark 2.6.

If Y is a nonempty convex subset of a t.v.s. with Γ=co , then Definition 2.5 (i) and (ii) reduce to Definition 2.4 (iii) and (vi) in Lin [5], respectively.

Definition 2.7 . (see [25]).

A uniformity for a set X is a nonempty family U of subsets of X×X satisfying the following conditions:

(i) : each member of U contains the diagonal Δ ,

(ii) : for each U∈U , ^U-1 ∈U ,

(iii) : for each U∈U , there exists V∈U such that V[composite function]V⊂U ,

(iv) : if U∈U , V∈U , then U∩V∈U ,

(v) : if U∈U and U⊂V⊂X×X , then V∈U .

The pair (X,U) is called a uniform space. Every member in U is called an entourage. For any x∈X and any U∈U , we define U[x]:={y∈X:(x,y)∈U} . The uniformity U is called separating if _... {U⊂X×X:U∈U}=Δ . The uniform space (X,U) is Hausdorff if and only if U is separating. For more details about uniform spaces, we refer the reader to Kelley [25].

Definition 2.8 . (see [12]).

An abstract convex uniform space (E,D;Γ;[Bernoulli]) is an abstract convex space with a basis [Bernoulli] of a uniformity of E .

Definition 2.9 . (see [12]).

An abstract convex uniform space (E⊃D;Γ;[Bernoulli]) is called an LΓ -space if

(i) : D is dense in E , and

(ii) : for each U∈[Bernoulli] and each Γ -convex subset A⊂E , the set {x∈E:A∩U[x]≠∅} is Γ -convex.

Lemma 2.10 . (see [12, Corollary 4.5 ]).

Let (E⊃D;Γ;[Bernoulli]) be a Hausdorff KKM LΓ -space and T:E...E a compact u.s.c. map with nonempty closed Γ -convex values. Then, T has a fixed point.

Lemma 2.11 . (see [24, Lemma 8.1 ]).

Let {(_Ei ,_Di ;_Γi )_}i∈I be any family of abstract convex spaces. Let E:=_∏i∈IEi and D:=_∏i∈IDi . For each i∈I , let _πi :D[arrow right]_Di be the projection. For each A∈...D... , define Γ(A):=_∏i∈IΓi (_πi (A)) . Then, (E,D;Γ) is an abstract convex space.

Lemma 2.12.

Let I be any index set. For each i∈I , let (_Xi ;_Γi ;_[Bernoulli]i ) be an LΓ -space. If one defines X:=_∏i∈IXi , Γ(A):=_∏i∈IΓi (_πi (A)) for each A∈...X... and [Bernoulli]:={^...j=1nUj :^Uj ∈...AE;,j=1,2,...,n and n∈...} , where ...AE;:={{(x,y)∈X×X:(_xi ,_yi )∈_Ui }:i∈I,_Ui ∈_[Bernoulli]i } . Then, (X;Γ;[Bernoulli]) is also an LΓ -space.

Proof.

By Lemma 2.11, (X;Γ) is an abstract convex space. It is easy to check that ...AE; is a subbase of the product uniformity of X . Since [Bernoulli] is the basis generated by ...AE; , we obtain that [Bernoulli] is a basis of the product uniformity, and the associated uniform topology on X .

Now, we prove that for each U∈[Bernoulli] and each Γ -convex subset A⊂X , the set {x∈X:A∩U[x]≠∅} is Γ -convex. Firstly, we show that for each i∈I , _πi (A) is a _Γi -convex subset of _Xi . For any _Ni ∈..._πi (A)... , we can find some N∈...A... with _πi (N)=_Ni . Since A is a Γ -convex subset of X , we have Γ(N)⊂A . It follows that _Γi (_πi (N))=_Γi (_Ni )⊂_πi (A) . Thus, we have shown that _πi (A) is a _Γi -convex subset of _Xi . Secondly, we show that the set {x∈X:A∩U[x]≠∅} is Γ -convex. Since each ^Uj ∈...AE; has the form ^Uj ={(x,y)∈X×X:(_xij ,_yij )∈_Uij } for some _ij ∈I and _Uij ∈_{[Bernoulli]ij} , we have that [figure omitted; refer to PDF] [figure omitted; refer to PDF] By the definition of LΓ -spaces, we obtain that for each j∈{1,2,...,n} , the set {_xij ∈_Xij :_πij (A)∩_Uij [_xij ]≠∅} is _Γij -convex. It follows from (2.6) that the set {x∈X:A∩U[x]≠∅} is a Γ -convex subset of X . Therefore (X;Γ;[Bernoulli]) is an LΓ -space. This completes the proof.

Remark 2.13.

Lemma 2.12 generalizes [26, Theorem 2.2 ] from locally FC -uniform spaces to LΓ -spaces. The proof of Lemma 2.12 is different with the proof of [26, Theorem 2.2 ].

3. Existence Theorems of Solutions for Systems of Generalized Quasivariational Inclusion Problems

Let I be any index set. For each i∈I , let _Zi be a topological vector space, (_Xi ;^Γi1 ;^{[Bernoulli]i1} ) be an LΓ -space, and (_Yi ;^Γi2 ;^{[Bernoulli]i2} ) be an LΓ -space with _1Yi ∈[real]...(_Yi ,_Yi ) . Let X=_∏i∈IXi , Y=_∏i∈IYi and (X×Y;Γ;[Bernoulli]) be the product LΓ -space as defined in Lemma 2.12. Furthermore, we assume that (X×Y;Γ;[Bernoulli]) is a KKM space. Throughout this paper, we use these notations unless otherwise specified, and assume that all topological spaces are Hausdorff.

The following theorem is the main result of this paper.

Theorem 3.1.

For each i∈I , suppose that

(i) _Ai :X×Y..._Xi is a compact u.s.c. map with nonempty closed ^Γi1 -convex values,

(ii) _Ti :X..._Yi is a compact continuous map with nonempty closed ^Γi2 -convex values,

(iii): _Gi :X×_Yi ×_Yi ..._Zi is a closed map with nonempty values,

(iv) for each (x,_vi )∈X×_Yi , _yi ..._Gi (x,_yi ,_vi ) is {0} -quasiconvex; for each (x,_yi )∈X×_Yi , _vi ..._Gi (x,_yi ,_vi ) is {0} -quasiconvex-like and 0∈_Gi (x,_yi ,_yi ) .

Then, there exists (x¯,y¯)∈X×Y with x¯=(_x¯i)i∈I and y¯=(_y¯i)i∈I such that for each i∈I , _x¯i ∈_Ai (x¯,y¯) , _y¯i ∈_Ti (x¯) and 0∈_Gi (x¯,_y¯i ,_vi ) for all _vi ∈_Ti (x¯) .

Proof.

For each i∈I , define _Hi :X..._Ti (X) by [figure omitted; refer to PDF] Then, _Hi (x) is nonempty for each x∈X . Indeed, fix any i∈I and x∈X , define ^Qix :_Ti (x)..._Ti (x) by [figure omitted; refer to PDF] First, we show that ^Qix is a KKM map w.r.t. _{1Ti (x)} . Suppose to the contrary that there exists a finite subset {^vi1 ,^vi2 ,...,^vin } ⊂_Ti (x) such that ^Γi2 ({^vi1 ,^vi2 ,...,^vin })⊄^...k=1nQix (^vik ) . Hence, there exists _v¯i ∈^Γi2 ({^vi1 ,^vi2 ,...,^vin }) satisfying _v¯i ∉^Qix (^vik ) for all k=1,2,...,n . Since _Ti (x) is ^Γi2 -convex, we have _v¯i ∈^Γi2 ({^vi1 ,^vi2 ,...,^vin })⊂_Ti (x) . By _v¯i ∉^Qix (^vik ) for all k=1,2,...,n , we know that 0∉_Gi (x,_v¯i ,^vik ) for all k=1,2,...,n . Since _vi ..._Gi (x,_v¯i ,_vi ) is {0} -quasiconvex-like, there exists 1≤j≤n such that [figure omitted; refer to PDF] This leads to a contradiction. Therefore, ^Qix is a KKM map w.r.t. _{1Ti (x)} . Next, we show that ^Qix (_vi ) is closed for each _vi ∈_Ti (x) . Indeed, if _yi ∈^Qix (_vi )¯ , then there exists a net {^yiα_}α∈Λ in ^Qix (_vi ) such that ^yiα [arrow right]_yi . For each α∈Λ , we have ^yiα ∈_Ti (x) and 0∈_Gi (x,^yiα ,_vi ) . By condition (ii), _Ti (x) is closed, and hence _yi ∈_Ti (x) . By condition (iii), _Gi is closed, and hence 0∈_Gi (x,_yi ,_vi ) . It follows that _yi ∈^Qix (_vi ) . Therefore, ^Qix (_vi ) is closed. Since _1Yi ∈[real]...(_Yi ,_Yi ) and _Ti (x) is ^Γi2 -convex, we have that _{1Ti (x)} ∈[real]...(_Ti (x),_Ti (x)) . Having that _Ti is compact, we can deduce that _{...vi ∈Ti (x)}^Qix (_vi )≠∅ . That is _Hi (x) is nonempty.

_Hi is closed for each i∈I . Indeed, if (x,_yi )∈Graph(_Hi )¯ , then there exists a net {(^xα ,^yiα )_}α∈Λ in Graph(_Hi ) such that (^xα ,^yiα )[arrow right](x,_yi ) . One has ^yiα ∈_Ti (^xα ) and 0∈_Gi (^xα ,^yiα ,_vi ) for all _vi ∈_Ti (^xα ) . By condition (ii), _Ti is closed, and hence _yi ∈_Ti (x) . Let _vi ∈_Ti (x) , since _Ti is l.s.c., there exists a net {^viα } satisfying ^viα ∈_Ti (^xα ) and ^viα [arrow right]_vi . We have 0∈_Gi (^xα ,^yiα ,^viα ) . Since _Gi is closed, we obtain 0∈_Gi (x,_yi ,_vi ) . Thus, we have shown that (x,_yi )∈Graph(_Hi ) . Hence, _Hi is closed.

_Hi (x) is ^Γi2 -convex for each i∈I and x∈X . Indeed, if {^yi1 ,^yi2 ,...,^yin }∈..._Hi (x)... , then we have that {^yi1 ,^yi2 ,...,^yin }⊂_Ti (x) and 0∈_Gi (x,^yik ,_vi ) for all _vi ∈_Ti (x) and all k=1,2,...,n . For any given _y¯i ∈^Γi2 ({^yi1 ,^yi2 ,...,^yin }) , we have _y¯i ∈_Ti (x) because _Ti (x) is ^Γi2 -convex. For each _vi ∈_Ti (x) , since _yi ..._Gi (x,_yi ,_vi ) is {0} -quasiconvex, there exists 1≤j≤n such that [figure omitted; refer to PDF] Hence, 0∈_Gi (x,_y¯i ,_vi ) for all _vi ∈_Ti (x) . It follows that _y¯i ∈_Hi (x) and _Hi (x) is ^Γi2 -convex.

Since _Hi (X)⊂_Ti (X)¯ and _Ti (X)¯ is compact. It follows from Lemma 2.2(ii) that _Hi is a compact u.s.c. map for each i∈I . Define Q:X×Y...X×Y by [figure omitted; refer to PDF] It follows from the above discussions that for each i∈I , _Hi is a compact u.s.c. map with nonempty closed ^Γi2 -convex values. Thus, Q is a compact u.s.c. map with nonempty closed Γ -convex values. By Lemma 2.10, there exists (x¯,y¯)∈X×Y such that (x¯,y¯)∈Q(x¯,y¯) . That is there exists (x¯,y¯)∈X×Y with x¯=(_x¯i)i∈I and y¯=(_y¯i)i∈I such that for each i∈I , _x¯i ∈_Ai (x¯,y¯) , _y¯i ∈_Ti (x¯) and 0∈_Gi (x¯,_y¯i ,_vi ) for all _vi ∈_Ti (x¯) . This completes the proof.

For the special case of Theorem 3.1, we have the following corollary which is actually an existence theorem of solutions for variational equations.

Corollary 3.2.

For each i∈I , suppose that conditions (i) and (ii) in Theorem 3.1 hold. Moreover,

(iii)₁ : _Gi :X×_Yi ×_Yi [arrow right]_Zi is a continuous mapping;

(iv)₁ : for each (x,_vi )∈X×_Yi , _yi [arrow right]_Gi (x,_yi ,_vi ) is {0} -quasiconvex; for each (x,_yi )∈X×_Yi , _vi [arrow right]_Gi (x,_yi ,_vi ) is also {0} -quasiconvex and _Gi (x,_yi ,_yi )=0 .

Then, there exists (x¯,y¯)∈X×Y with x¯=(_x¯i)i∈I and y¯=(_y¯i)i∈I such that for each i∈I , _x¯i ∈_Ai (x¯,y¯) , _y¯i ∈_Ti (x¯) and _Gi (x¯,_y¯i ,_vi )=0 for all _vi ∈_Ti (x¯) .

Theorem 3.3.

For each i∈I , suppose that conditions (i) and (ii) in Theorem 3.1 hold. Moreover,

(iii)₂ : _Hi :X..._Zi is a closed map with nonempty values and _Qi :X×_Yi ×_Yi ..._Zi is an u.s.c. map with nonempty compact values;

(iv)₂ : for each (x,_vi )∈X×_Yi , _yi ..._Qi (x,_yi ,_vi ) is {0} -quasiconvex; for each (x,_yi )∈X×_Yi , _vi ..._Qi (x,_yi ,_vi ) is {0} -quasiconvex-like and 0∈_Hi (x)+_Qi (x,_yi ,_yi ) .

Then, there exists (x¯,y¯)∈X×Y with x¯=(_x¯i)i∈I and y¯=(_y¯i)i∈I such that for each i∈I , _x¯i ∈_Ai (x¯,y¯) , _y¯i ∈_Ti (x¯) and 0∈_Hi (x¯)+_Qi (x¯,_y¯i ,_vi ) for all _vi ∈_Ti (x¯) .

Proof.

For each i∈I , define _Gi :X×_Yi ×_Yi ..._Zi by [figure omitted; refer to PDF] Obviously, _Gi has nonempty values. Now, we show that _Gi is closed. Indeed, if (x,_yi ,_vi ,_zi )∈Graph(_Gi )¯ , then there exists a net {(^xα ,^yiα ,^viα ,^ziα )_}α∈Λ in Graph(_Gi ) such that (^xα ,^yiα ,^viα ,^ziα )[arrow right](x,_yi ,_vi ,_zi ) . Since [figure omitted; refer to PDF] there exist ^uiα ∈_Hi (^xα ) and ^wiα ∈_Qi (^xα ,^yiα ,^viα ) such that ^ziα =^uiα +^wiα . Let [figure omitted; refer to PDF] Then K is a compact subset of X , _Li and _Mi are compact subsets of _Yi . By condition (iii)₂ and Lemma 2.2(iii), _Qi (K×_Li ×_Mi ) is a compact subset of _Zi . Thus, we can assume that ^wiα [arrow right]_wi . By condition (iii)₂ , _Qi is closed, and hence _wi ∈_Qi (x,_yi ,_vi ) . Since ^ziα -^wiα =^uiα ∈_Hi (^xα ) and _Hi is closed, we have _zi -_wi ∈_Hi (x) . Letting _ui =_zi -_wi , it follows that [figure omitted; refer to PDF] and so _Gi is closed.

By the above discussions, we know that condition (iii) of Theorem 3.1 is satisfied. It is easy to check that condition (iv) of Theorem 3.1 is also satisfied. By Theorem 3.1, there exists (x¯,y¯)∈X×Y with x¯=(_x¯i)i∈I and y¯=(_y¯i)i∈I such that for each i∈I , _x¯i ∈_Ai (x¯,y¯) , _y¯i ∈_Ti (x¯) and [figure omitted; refer to PDF] for all _vi ∈_Ti (x¯) . This completes the proof.

For the special case of Theorem 3.3, we have the following corollary which is actually an existence theorem of solutions for variational equations.

Corollary 3.4.

For each i∈I , suppose that conditions (i) and (ii) in Theorem 3.1 hold. Moreover,

(iii)₃ : _Hi :X[arrow right]_Zi is a continuous map and _Qi :X×_Yi ×_Yi [arrow right]_Zi is a continuous map;

(iv)₃ : for each (x,_vi )∈X×_Yi , _yi [arrow right]_Qi (x,_yi ,_vi ) is {0} -quasiconvex; for each (x,_yi )∈X×_Yi , _vi [arrow right]_Qi (x,_yi ,_vi ) is also {0} -quasiconvex and _Hi (x)+_Qi (x,_yi ,_yi )=0 .

Then, there exists (x¯,y¯)∈X×Y with x¯=(_x¯i)i∈I and y¯=(_y¯i)i∈I such that for each i∈I , _x¯i ∈_Ai (x¯,y¯) , _y¯i ∈_Ti (x¯) and _Hi (x¯)+_Qi (x¯,_y¯i ,_vi )=0 for all _vi ∈_Ti (x¯) .

From Theorem 3.3, we establish the following corollary which is actually an existence theorem of solutions for systems of generalized vector quasiequilibrium problems.

Corollary 3.5.

For each i∈I , suppose that conditions (i) and (ii) in Theorem 3.1 hold. Moreover,

(iii)₄ : _Ci :X..._Zi is a closed map with nonempty values and _Qi :X×_Yi ×_Yi ..._Zi is an u.s.c. map with nonempty compact values;

(iv)₄ : for each (x,_vi )∈X×_Yi , _yi ..._Qi (x,_yi ,_vi ) is {0} -quasiconvex; for each (x,_yi )∈X×_Yi , _vi ..._Qi (x,_yi ,_vi ) is {0} -quasiconvex-like and _Qi (x,_yi ,_yi )∩_Ci (x)≠∅ .

Then, there exists (x¯,y¯)∈X×Y with x¯=(_x¯i)i∈I and y¯=(_y¯i)i∈I such that for each i∈I , _x¯i ∈_Ai (x¯,y¯) , _y¯i ∈_Ti (x¯) , and _Qi (x¯,_y¯i ,_vi )∩_Ci (x¯)≠∅ for all _vi ∈_Ti (x¯) .

Proof.

Define _Hi :X..._Zi by _Hi (x)=-_Ci (x) for all x∈X . Since _Ci is a closed map with nonempty values, we have that _Hi is a closed map with nonempty values. All the conditions of Theorem 3.3 are satisfied. The conclusion of Corollary 3.5 follows from Theorem 3.3. This completes the proof.

4. Applications to Optimization Problems

Let Z be a real topological vector space, D a proper convex cone in Z . A point y¯∈A is called a vector minimal point of A if for any y∈A , y-y¯∉-D\{0} . The set of vector minimal point of A is denoted by Mi_nD A .

Lemma 4.1 . (see [27]).

Let Z be a Hausdorff t.v.s., D be a closed convex cone in Z . If A is a nonempty compact subset of Z , then _{Min D} A≠∅ .

Theorem 4.2.

For each i∈I , suppose that conditions (i), (ii) in Theorem 3.1 and conditions (iii)₄ , (iv)₄ in Corollary 3.5 hold. Furthermore, let h:X×Y...Z be an u.s.c. map with nonempty compact values, where Z is a real t.v.s. ordered by a proper closed convex cone in Z . Then, there exists a solution to: [figure omitted; refer to PDF] where x=(_xi)i∈I and y=(_yi)i∈I such that for each i∈I , _xi ∈_Ai (x,y) , _yi ∈_Ti (x) , and _Qi (x,_yi ,_vi )∩_Ci (x)≠∅ for all _vi ∈_Ti (x) .

Proof.

By Corollary 3.5, there exists (x¯,y¯)∈X×Y with x¯=(_x¯i)i∈I and y¯=(_y¯i)i∈I such that for each i∈I , _x¯i ∈_Ai (x¯,y¯) , _y¯i ∈_Ti (x¯) and _Qi (x¯,_y¯i ,_vi )∩_Ci (x¯)≠∅ for all _vi ∈_Ti (x¯) . For each i∈I , let [figure omitted; refer to PDF] and M=_...i∈IMi . Then (x¯,y¯)∈M and M≠∅ . We show that _Mi is closed for each i∈I . Indeed, if (x,y)∈_Mi ¯ , then there exists a net {(^xα ,^yα )_}α∈Λ in _Mi such that (^xα ,^yα )[arrow right](x,y) . For each α∈Λ , (^xα ,^yα )∈_Mi implies that [figure omitted; refer to PDF] By the closedness of _Ai and _Ti , we have that _xi ∈_Ai (x,y) and _yi ∈_Ti (x) . Now, we prove that _Qi (x,_yi ,_vi )∩_Ci (x)≠∅ for all _vi ∈_Ti (x) . For any _vi ∈_Ti (x) , since _Ti is l.s.c., there exists a net {^viα_}α∈Λ satisfying ^viα ∈_Ti (^xα ) and ^viα [arrow right]_vi . Let ^uiα ∈_Qi (^xα ,^yiα ,^viα )∩_Ci (^xα ) . Since _Qi is u.s.c. with nonempty compact values, we can assume that ^uiα [arrow right]_ui ∈_Zi . By the closedness of _Qi and _Ci , we have that _ui ∈_Qi (x,_yi ,_vi )∩_Ci (x) . Thus, _Qi (x,_yi ,_vi )∩_Ci (x)≠∅ . It follows that _Mi is closed. Hence, M is closed. Note that M⊂_∏i∈IAi (X×Y)×_∏i∈ITi (X) . We know that M is a nonempty compact subset of X×Y . It follows from Lemma 2.2(iii) that h(M) is a nonempty compact subset of Z . By Lemma 4.1, Mi_nD h(M)≠∅ . That is there exists a solution of the problem: Mi_n(x,y) h(x,y) where (x,y)∈M . This completes the proof.

Theorem 4.3.

For each i∈I , suppose that _Xi is compact and condition (ii) in Theorem 3.1 holds. Moreover,

(iii)₅ : _Qi :X×_Yi ×_Yi [arrow right]... is a continuous function;

(iv)₅ : for each (x,_vi )∈X×_Yi , _yi [arrow right]_Qi (x,_yi ,_vi ) is {0} -quasiconvex; for each (x,_yi )∈X×_Yi , _vi [arrow right]_Qi (x,_yi ,_vi ) is also {0} -quasiconvex and _Qi (x,_yi ,_yi )≥0 .

Furthermore, let h:X×Y[arrow right]... is a l.s.c. function. Then there exists a solution to: [figure omitted; refer to PDF] where x=(_xi)i∈I and y=(_yi)i∈I such that for each i∈I , _yi ∈_Ti (x) and _Qi (x,_yi ,_vi )≥0 for all _vi ∈_Ti (x) .

Proof.

For each i∈I , define _Ai :X×Y..._Xi and _Ci :X...... by [figure omitted; refer to PDF] respectively. It is easy to check that all the conditions of Corollary 3.5 are satisfied. For each i∈I , define [figure omitted; refer to PDF] and M=_...i∈IMi . Then, by Corollary 3.5, there exists (x¯,y¯)∈M and hence M≠∅ . Arguing as Theorem 4.2, we can prove that M is a nonempty compact subset of X×Y . Hence there exists a solution to the problem mi_n(x,y) h(x,y) where (x,y)∈M . This completes the proof.

Remark 4.4.

Theorem 4.3 generalizes [28, Corollary 3.5] from locally convex topological vector spaces to LΓ -spaces.

Theorem 4.5.

For each i∈I , suppose that _Xi is compact and condition (ii) in Theorem 3.1 holds. Moreover,

(iii)₆ : _Fi :X×_Yi [arrow right]... is a continuous function;

(iv)₆ : for each x∈X , _yi [arrow right]_Fi (x,_yi ) is {0} -quasiconvex.

Furthermore, let h:X×Y[arrow right]... be a l.s.c. function. Then, there exists a solution to the problem: [figure omitted; refer to PDF] where x=(_xi)i∈I and y=(_yi)i∈I such that for each i∈I , _yi is the solution of the problem _{min vi ∈Ti (x)Fi} (x,_vi ) .

Proof.

For each i∈I , define _Qi :X×_Yi ×_Yi [arrow right]... by [figure omitted; refer to PDF] It is easy to check that all the conditions of Theorem 4.3 are satisfied. Theorem 4.5 follows immediately from Theorem 4.3. This completes the proof.

Acknowledgments

This work was supported by the Key Program of NSFC (Grant no. 70831005) and the Open Fund (PLN0904) of State Key Laboratory of Oil and Gas Reservoir Geology and Exploitation (Southwest Petroleum University).