1. Introduction
The notion of the resolvent for convex functions is one of the most important subjects in the convex minimization problems. We have proposed various resolvents in many spaces and have studied their properties. Moreover, the asymptotic behavior of resolvents at infinity includes crucial problems in studying the properties of resolvents. There are results on the asymptotic behavior of the resolvent of convex functions at infinity. For example, in a Hilbert space
H, for a proper lower semicontinuous convex function
, a resolvent
is defined by the following:
for all
. As the asymptotic behavior of this resolvent, the following result is found.
Theorem 1 (See [
1])
. Let H be a Hilbert space and a proper lower semicontinuous convex function. For each , if is bounded by some sequence such that , then and On the other hand, geodesic spaces are metric spaces which have some convex structures. In geodesic spaces, many types of resolvents are also proposed and studied. A complete CAT(0) space, which is an example of a geodesic space, is a generalization of Hilbert spaces. In this space, the following resolvent is proposed (see [
2]). Let
X be a complete CAT(0) space and
a proper lower semicontinuous convex function. We define the resolvent
of
f by the following equation:
for all
. For this resolvent, we can also consider asymptotic behavior at infinity and have results similar to Theorem 1 (see [
3]). In these cases, a convex function
f is fixed. In a Banach space, the convergence of a sequence for resolvents of maximal monotone operators has been considered in many papers. For example, see [
4,
5,
6,
7,
8,
9,
10].
Therefore, we will also consider the convergent sequence of convex functions
and their resolvents. We characterize the convergence of a sequence of convex functions by using the set convergence of minimizers. Mosco convergence is one of the useful notions of set convergence. It is defined in Banach spaces and complete admissible CAT(
) spaces. See [
11,
12,
13] for more details.
This paper considers the asymptotic behavior of the resolvents of a given convergent sequence of convex functions on a complete CAT space and a complete admissible CAT space. As a convergence of a sequence of convex functions , we suppose that , the sequence of sets of minimizers of , is convergent in the sense of Mosco.
2. Preliminaries
Let
X be a metric space. For
,
is called a geodesic with the endpoints
x and
y if
satisfies the following:
We say that
X is a uniquely geodesic space if there exists
uniquely for each
. For
, a geodesic segment
joining
x and
y is an image of
defined by
. A convex combination
z between
x and
y is a point of
such that
and
, and we denote this
z by
. Let
X be a uniquely geodesic space and
. A geodesic triangle
with vertices
,
,
is defined by
. For a geodesic triangle
, a comparison triangle
is defined as a triangle whose vertices
satisfy
. Furthermore, for
(
and
), a comparison point
of
p is a point on
such that
.
X is called a CAT
space if for any geodesic triangle
, any
, and their comparison points
, the following holds:
Let
X be a geodesic space and
a geodesic triangle on
X. In the same way as above, we define a comparison triangle
.
X is called a CAT
space if for any geodesic triangle
with
, any
, and their comparison points
, it holds that:
An admissible CAT space is a CAT space such that the distance of any two points is smaller than . Let X be an admissible CAT space and a sequence of X. The sequence is said to be spherically bounded if there exists such that for all .
We describe the fundamental properties of complete CAT(0) spaces and complete admissible CAT(1) spaces. The following inequalities are called parallelogram laws.
Theorem 2 (See [
3,
14])
. Let X be a complete CAT
space, , and . Then, Theorem 3 (See [
14])
. Let X be a complete admissible CAT(1)
space, , and . Then,In particular, for , it holds that:or equivalently, that: Let
X be a metric space and
a bounded sequence in
X. For
, we assign the following equation:
Then, if
satisfies
, it is called an asymptotic center of
. Moreover, if for any subsequence of
its asymptotic center is a unique point
x, we say that
is
-convergent to
x. Any bounded sequences in complete CAT
space have a
-convergent subsequence. Likewise, any spherically bounded sequences in complete admissible CAT
have a
-convergent subsequence. See [
15,
16,
17].
Let
X be a complete CAT
or complete admissible CAT
space, and
C a closed convex subset of
X. Then, for
, there exists a unique
such that:
We define
by the following:
for
. This
is called a metric projection onto
C and has the following properties. If
X is a complete CAT
space, then
for all
and
. If
X is a complete admissible CAT
space, then
for all
and
.
Let
be nonempty closed convex subsets of a complete CAT(0) or complete admissible CAT(1) space
X. We define the sets d-
and
Δ-
as follows:
if and only if there exists
such that
and
for each
n;
if and only if there exists a bounded sequence
such that
and
for each
i. If a closed convex subset
of
X satisfies the following:
we say that
converges to
in the sense of Mosco and denote M-
.
3. Main Results
Let be the proper convex lower semicontinuous functions on a CAT(0) or complete admissible CAT(1) space X. As the convergence of a sequence of convex functions , we suppose the following conditions:
- (a)
;
- (b)
For all , there exists such that and ;
- (c)
For any subsequence of and a -convergent sequence whose -limit is , it holds that .
We consider the asymptotic behavior of a resolvent on CAT(0) space. Let X be a complete CAT space, a proper convex lower semicontinuous function, and . We say that a function satisfies the condition (A) if the following conditions hold:
is increasing;
is continuous;
is strictly convex for all ;
as , for all constants .
If
satisfies the condition (A), then the function
has a unique minimizer. We define a resolvent
of
f with
by the following equation:
for
. For example,
and
satisfies these conditions. If we define the resolvent with
, it is the resolvent described in the Introduction. For complete CAT(
) spaces, which are a special case of CAT(0) spaces, the resolvent with
is defined and studied in [
18].
Now we describe the asymptotic behavior of resolvents for a sequence of convex functions satisfying (a), (b), and (c).
Theorem 4. Let X be a complete CAT(0)
space, a sequence of proper convex lower semicontinuous functions from X to , f a proper convex lower semicontinuous function from X to , and an increasing sequence diverging to ∞. If and f satisfy the conditions (a), (b), and (c), then for , we have: Proof. Let
. We put
and
. Since
from the condition (a), there exists
such that
for each
n and
. Since points
and
are minimizers of
and
, respectively, then we have the follwing equation:
Thus, we get
, which is equivalent to
. Since
is a convergent sequence, and
is bounded, this implies that
is also bounded. Take a subsequence
of
arbitrarily. There exists a
-convergent subsequence
of
to some
. From the condition (b), there exists
such that
and
. Furthermore, using the condition (c), we get
as
. From the definition of the resolvent, we have the following equation:
By the boundedness of
and
, letting
, we have the following:
This implies that
. Since
, we let
again and get the following:
Hence, we have
and
. Since
is a minimizer of
and
is convex, we have the following equations:
and hence,
From the parallelogram law of CAT(0) space, we get the following:
Since both
and
are convergent to
, we have:
which implies that
. Then, any subsequence
of
has a convergent subsequence
, which tends to
p. From these facts, we get a desired result. □
From this theorem, we have the following corollaries. Suppose for all . Then obviously satisfies the conditions (a), (b), and (c).
Corollary 1. Let X be a complete CAT(0)
space, f a proper convex lower semicontinuous function from X to , and a function satisfying the condition (A). For a positive real number λ, define by the following equation:for . Then, for each , Let be a sequence of nonempty closed convex subsets which converges to C in the sense of Mosco. If and , then and , where is the indicator function of C. Since converges to C, and satisfy the condition (a). They also satisfy the conditions (b) and (c).
Corollary 2. Let X be a complete CAT(0)
space, a sequence of nonempty closed convex subsets of X, and C a nonempty closed convex subset of X. If converges to C in the sense of Mosco, then for each , Similarly, we consider asymptotic behavior of a resolvent on CAT(1) space. Let X be a complete admissible CAT(1) space. We say satisfies the condition (B) if the following hold:
Then, the set
is a singleton for all
, and we define
in a similar way. For example,
and
satisfy the conditions above. On complete admissible CAT(1) spaces, resolvents by using these functions are defined and their properties are studied in [
19,
20].
We consider that the asymptotic behavior of resolvents for a sequence of convex functions satisfies (a), (b), and (c).
Theorem 5. Let X be a complete admissible CAT(1)
space, a sequence of proper convex lower semicontinuous functions from X to , f a proper convex lower semicontinuous function from X to , and an increasing sequence diverging to ∞. If and f satisfy the conditions (a), (b), and (c), then for , Proof. In the same way as the proof of Theorem 5, if we take
with the same procedure, it hold that
and
From the parallelogram law of CAT(1) space, we get the following equations:
This implies that , and we get . □
As well as for the case of CAT(0) spaces, we obtain the following corollaries in CAT(1) spaces.
Corollary 3. Let X be a complete admissible CAT(1)
space, f a proper convex lower semicontinuous function from X to , and a function satisfying the condition (B). For a positive real number λ, define by the following equation:for . Then, for each , we have: Corollary 4. Let X be a complete admissible CAT(1)
space, a sequence of nonempty closed convex subsets of X, and C a nonempty closed convex subset of X. If converges to C in the sense of Mosco, then for each , we have: 4. Applications to Hilbert Spaces
Finally, we consider the applications of our results to the case of a Hilbert space. Because the class of complete CAT(0) spaces includes that of Hilbert spaces, we can get some results in Hilbert spaces directly. The definitions of conditions for functions and are applied to those in CAT(0) spaces.
Theorem 6. Let H be a Hilbert space, a sequence of proper convex lower semicontinuous functions from X to , f a proper convex lower semicontinuous function from X to , and an increasing sequence diverging to ∞. Suppose and f satisfy the conditions (a), (b), and (c), and satisfies the condition (A). Define by the following:for . Then, for each Using this result, we can get following famous theorems. First, if we consider the case that a convex function is fixed and , we can get Theorem 1. Next, considering the case that convex functions are the indicator functions of some convex sets, we obtain the following theorem.
Theorem 7 (See [
21])
. Let H be a Hilbert space, a sequence of nonempty closed convex subsets of X, and C a nonempty closed convex subset of X. If converges to C in the sense of Mosco, then for each , In conclusion, we summarize the results in this paper. For a given sequence of proper lower semicontinuous functions converging to f in the sense of the conditions (a), (b), and (c), we consider the corresponding sequence of resolvents with a positive real sequence diverging to ∞. The main results imply the pointwise convergence of this sequence to the metric projection onto in the setting of a CAT(0) and a CAT(1) space, respectively. We can apply them to the asymptotic behavior of the resolvent for a single function at ∞, and a convergence theorem for a sequence of metric projections.