Total Lagrange duality for DC infinite optimization problems

We present some total Lagrange duality results for inequality systems involving infinitely many DC functions. By using properties of the subdifferentials of involved functions, we introduce some new notions of constraint qualifications. Under the new constraint qualifications, we provide necessary and/or sufficient conditions for the stable total Lagrange duality to hold.

MSC:90C26, 90C46.

Let X be a real locally convex Hausdorff topological vector space, whose dual space $X^{\ast }$ is endowed with the weak^∗ topologies $W^{\ast }(X^{\ast },X)$. Let T be an arbitrary (possibly infinite) index set, C be a nonempty convex subset of X, and let $h,h_t:X\to \overline{\mathbb{R}}:=\mathbb{R}\cup \{+\mathrm{\infty }\}$, $t\in T$, be proper convex functions. Consider the following optimization problem (cf. [1–13] and the references therein):

and its Lagrange dual problem

where ${\mathbb{R}}_{+}^{(T)}$ is the cone consisting of vector $({\lambda }_t)\in {\mathbb{R}}^T$ with nonnegative and only finitely many nonzero coordinates, that is,

The optimal values of problems $(\mathcal{P})$ and $(\mathcal{D})$ are denoted by $v(\mathcal{P})$ and $v(\mathcal{D})$, respectively.

Usually, there is a so-called duality gap between the optimal values of primal problem $(\mathcal{P})$ and its Lagrange dual problem $(\mathcal{D})$. A challenge in convex analysis is to give sufficient conditions which guarantee the strong Lagrange duality, that is, $v(\mathcal{P})=v(\mathcal{D})$ and the dual problem $(\mathcal{D})$ has an optimal solution. Several sufficient and/or necessary conditions were given in the past in order to eliminate the above-mentioned duality gap, see, for example, [1–3, 5] and the references therein. In particular, the authors in [5] established a complete characterization for the strong Lagrange duality under assumption that f and $f_t$ are not necessarily convex, and in [14], the authors considered the optimization problem $(\mathcal{P})$, but with $h:=f-g$ and $h_t:=f_t-g_t$, $t\in T$ being DC (difference of two convex functions) functions, and they obtained some complete characterizations for the weak and strong Lagrange dualities. As pointed in [15], problems of DC programming are highly important from both viewpoints of optimization theory and applications, and they have been extensively studied in the literature (cf. [15–24] and the references therein).

Inspired by the works mentioned above, we continue to study the optimization problem which was studied in [14], that is,

where T, C are as in (1.1), $f,g,f_t,g_t:X\to \overline{\mathbb{R}}$, $t\in T$, are proper convex functions. Throughout this paper, we assume that

Following [14], we define the Lagrange function $L:H^{\ast }\times {\mathbb{R}}_{+}^{(T)}\to \overline{\mathbb{R}}$ for the DC optimization problem (1.3) by

for any $(w^{\ast },\lambda )\in H^{\ast }\times {\mathbb{R}}_{+}^{(T)}$ with $w^{\ast }=(u^{\ast },(v_t^{\ast }))\in H^{\ast }:=dom{g}^{\ast }\times {\prod }_{t\in T}dom{g}_t^{\ast }$ and $\lambda =({\lambda }_t)\in {\mathbb{R}}_{+}^{(T)}$. Then the Lagrange dual problem for the DC optimization problem (1.3) is defined by

where and throughout the whole paper, following [[25], p.39], we adopt the convention that $(+\mathrm{\infty })+(-\mathrm{\infty })=(+\mathrm{\infty })-(+\mathrm{\infty })=+\mathrm{\infty }$ and $0\cdot (\mathrm{\infty })=0$. Then, for any two proper convex functions $h_1,h_2:X\to \overline{\mathbb{R}}$, we have that

hence,

As mentioned in [14], in the case when g and $g_t$, $t\in T$ are lsc, then the dual problem (1.5) is equivalent to the following problem

However, without assuming the lower semicontinuity of g and $g_t$, problems (1.8) and $(D)$ are in general not equivalent.

The present paper is centered around the total Lagrangian duality for the DC problem $(P)$ and its dual problem $(D)$. For the problem of total Lagrange duality, one seeks conditions ensuring that the following implication holds for $x_0\in dom(f-g)\cap A$:

Clearly, the strong Lagrange duality ensures the total Lagrange duality, but the converse does not necessarily hold in general. To our knowledge, not many results are known to provide complete characterizations for the total Lagrangian duality for the DC optimization problem (1.3). Except the works in paper [6] by Fang et al., where, assuming in addition that $g=g_t=0$, $t\in T$, a complete characterization was established for the stable total Lagrangian duality for problem (1.3), that is, the characterization for (1.9) to hold for $f+p$ in place of f with any $p\in X^{\ast }$. However, the approaches in [6] do not work for the DC optimization problem (1.3).

In this paper, we do not impose any topological assumption on C or on f, g, $f_t$ and $g_t$, that is, C is not necessarily closed, and f, g, $f_t$, $t\in T$ are not necessarily lsc, and $g_t$, $t\in T$ are necessarily differentiable. One of our main aims in the present paper is to use these constraint qualifications (or their variations) involving subdifferentials, which have been studied and extensively used, see, for example, [2, 3, 6, 12, 26], to provide characterizations for the total Lagrangian duality. Most of results obtained in the present paper seem new and are proper extensions of the results in [6] in the special case when $g=g_t=0$, $t\in T$. In particular, both our dual problem and the regularity conditions introduced here are defined in terms of subdifferential of the convex functions f, g, $f_t$ and $g_t$ rather than those of the DC functions $f-g$ and $f_t-g_t$, which are different from the consideration in [6].

The paper is organized as follows. The next section contains the necessary notations and preliminary results. In Section 3, we provide some characterizations for the weak Lagrange dualities and the total Lagrangian dualities to hold.

The notations used in this paper are standard (cf. [25]). In particular, we assume throughout the whole paper that X is a real locally convex space, and let $X^{\ast }$ denote the dual space of X. For $x\in X$ and $x^{\ast }\in X^{\ast }$, we write $〈x^{\ast },x〉$ for the value of $x^{\ast }$ at x, that is, $〈x^{\ast },x〉:=x^{\ast }(x)$. Let Z be a set in X. The closure of Z is denoted by clZ. If $W\subseteq X^{\ast }$, then clW denotes the weak^∗ closure of W. For the whole paper, we endow $X^{\ast }\times \mathbb{R}$ with the product topology of $w^{\ast }(X^{\ast },X)$ and the usual Euclidean topology.

Following [27], we use ${\mathbb{R}}^{(T)}$ to denote the space of real tuples $\lambda ={({\lambda }_t)}_{t\in T}$ with only finitely many ${\lambda }_t\ne 0$, and let ${\mathbb{R}}_{+}^{(T)}$ denote the nonnegative cone in ${\mathbb{R}}^{(T)}$, that is,

The normal cone of the nonempty set Z at $z_0\in Z$ is denoted by $N_Z(z_0)$ and is defined by

and the indicator function ${\delta }_Z$ of Z is defined by

Let f be a proper function defined on X. We use domf, epif and $f^{\ast }$ to denote respectively the effective domain, the epigraph and the conjugate function of f, that is,

and

Let $x\in X$. The subdifferential of f at x is defined by

if $x\in domf$, and $\partial f(x):=\mathrm{\varnothing }$, otherwise. Then by definition,

By [[25], Theorems 2.3.1 and 2.4.2(iii)], the Young-Fenchel inequality below holds

and the Young equality holds

Furthermore, if g, h are proper functions, then

and

The closure of f is denoted by clf, which is defined by

Then (cf. [[25], Theorems 2.3.1]),

By [[25], Theorem 2.3.4], if clf is proper and convex, then the following equality holds:

Moreover, by [[25], Theorem 2.4.1], if $\partial f(x)\ne \mathrm{\varnothing }$, then

Finally, note that an element $p\in X^{\ast }$ can be naturally regarded as a function on X in such way that

Then the following facts are clear for any $a\in \mathbb{R}$ and a real-valued proper function f:

and

Unless explicitly stated otherwise, let f, g, T, C, $\{f_t,g_t:t\in T\}$ and A be as in Section 1, namely, T is an index set, $C\subseteq X$ is a convex set, f, g, $f_t$, $g_t$, $t\in T$ are proper convex functions on X such that $f-g$ and $f_t-g_t$, $t\in T$ are proper, and A is the solution set of the following system:

Then by (1.7), we have that

To avoid the triviality, we always assume that $A\cap dom(f-g)\ne \mathrm{\varnothing }$. For simplicity, we denote

and

To make the dual problem considered here well defined, we further assume that clg and $cl{g}_t$, $t\in T$ are proper. Then $H^{\ast }\ne \mathrm{\varnothing }$. For the whole paper, any elements $\lambda \in {\mathbb{R}}^{(T)}$ and $v^{\ast }\in {\prod }_{t\in T}dom{g}_t^{\ast }$ are understood as $\lambda =({\lambda }_t)\in {\mathbb{R}}^{(T)}$ and $v^{\ast }=(v_t^{\ast })\in {\prod }_{t\in T}dom{g}_t^{\ast }$, respectively.

Replacing f by all of its linear perturbed functions $f-p$, where $p\in X^{\ast }$, we consider the following DC infinite optimization problem

and its dual problem

where the Lagrange function $L_p:H^{\ast }\times {\mathbb{R}}_{+}^{(T)}\to \overline{\mathbb{R}}$ is defined by

for any $(w^{\ast },\lambda )\in H^{\ast }\times {\mathbb{R}}_{+}^{(T)}$ with $w^{\ast }=(u^{\ast },v^{\ast })\in H^{\ast }$ and $\lambda =({\lambda }_t)\in {\mathbb{R}}_{+}^{(T)}$. In particular, in the case when $p=0$, problem $(P_p)$, as well as its dual problem $(D_p)$, are reduced to problem $(P)$, and its dual problem $(D)$ as defined in (1.3) and (1.5), respectively.

Let $v(P_p)$ and $v(D_p)$ denote the optimal values of $(P_p)$ and $(D_p)$, respectively. For each $p\in X^{\ast }$, we use $S(P_p)$ to denote the optimal solution set of $(P_p)$. In particular, we write $S(P)$ for $S(P_0)$. Obviously, for each $p\in X^{\ast }$, $S(P_p)\subseteq A$. This section is devoted to the study of characterizing the total Lagrange dualities. Unlike the convexity case, the cases for DC optimization problems are more complicated. We begin with the following definition, where the notations of the weak Lagrange duality and the stable weak Lagrange duality were introduced in [14].

Definition 3.1 Let $X_0$ be a subset of X. Between problems $(P)$ and $(D)$, we say that

1. (i)

   the weak Lagrange duality holds if $v(D)\le v(P)$;

2. (ii)

   the stable weak Lagrange duality holds if $v(D_p)\le v(P_p)$ for each $p\in X^{\ast }$;

3. (iii)

   the stable $X_0$-total Lagrange duality holds if, for each $p\in X^{\ast }$, $v(P_p)=v(D_p)$ and problem $(D_p)$ has an optimal solution provided that $S(P_p)\cap X_0\ne \mathrm{\varnothing }$. In particular, in the case when $X_0=X$, the stable $X_0$-total duality is called the stable total duality.

Unlike the convexity case, the weak Lagrange duality does not necessarily hold in general as shown in [[14], Example 3.1]. In order to provide some sufficient conditions ensuring the weak Lagrange duality, we consider the following optimization problem, which plays a bridging role for our study:

where $p\in X^{\ast }$. Let $A^{cl}$ denote the solution set of the system $\{x\in C;f_t(x)-(cl{g}_t)(x)\le 0,t\in T\}$, that is,

Then, $A^{cl}\subseteq A$. As usual, we use $v(P_p^{cl})$ to define the optimal value of problem $(P_p^{cl})$. Then,

Moreover, by [[14], (1.5)], we see that

Thus, if g and $g_t$, $t\in T$, are lsc, then the weak Lagrange duality holds. The following proposition provides a weaker condition for the weak Lagrange duality to hold.

Proposition 3.1 Let $x_0\in S(P)$. Suppose that g and each $g_t$ are lsc at $x_0$. Then the weak Lagrange duality holds.

Proof Since $x_0\in S(P)$, it follows that

Note that g and each $g_t$ are lsc at $x_0$. Then for each $x\in X$,

the last inequality holds because $clg\le g$ and $A^{cl}\subseteq A$. This implies that $v(P)=v(P^{cl})$. Hence, by (3.11), one gets $v(D)\le v(P)$ and the proof is complete. □

Let ${\mathrm{\Omega }}_0$ denote the set of all points $x\in X$ such that $\partial H(x)\ne \mathrm{\varnothing }$. Below we will make use of the subdifferential $\partial h(x)$ for a general proper function (not necessarily convex) $h:X\to \overline{\mathbb{R}}$; see (2.1). Clearly, the following equivalence holds:

Form (2.9), if $x_0\in {\mathrm{\Omega }}_0$, then g and each $g_t$ are lsc at $x_0$. Hence, the following corollary follows from Proposition 3.1 directly.

Corollary 3.1 Let $p\in X^{\ast }$. If $S(P_p)\cap {\mathrm{\Omega }}_0\ne \mathrm{\varnothing }$, then $v(D_p)\le v(P_p)$.

Motivating by [20], we introduce the following condition (LSC) to characterize the relationships between $(P)$ and $(P^{cl})$ and the weak Lagrange duality.

Definition 3.2 The family $\{f,g,{\delta }_C;f_t,g_t:t\in T\}$ is said to satisfy the lower semi-continuity closure (LSC) if

Remark 3.1

1. (a)

   Since $clg\le g$ and $A^{cl}\subseteq A$, it follows that $f-g+{\delta }_A\le f-clg+{\delta }_{A^{cl}}$. Hence, by (2.5), the family $\{f,g,{\delta }_C;f_t,g_t:t\in T\}$ satisfies the (LSC) if and only if

   $$epi{(f-g+{\delta }_A)}^{\ast }\supseteq epi{(f-clg+{\delta }_{A^{cl}})}^{\ast }.$$

   (3.15)
2. (b)

   Obviously, if g and $g_t$, $t\in T$ are lsc, then the (LSC) holds. But the converse is not true, in general, as to be shown by Example 3.1 below.

Example 3.1 Let $X=C:=\mathbb{R}$, and let $T:=\{1\}$. Let $f,g,f_1,g_1:\mathbb{R}\to \overline{\mathbb{R}}$ be defined respectively by

$f_1:={\delta }_{[0,+\mathrm{\infty })}$ and $g_1:=0$. Then f, g, $f_1$, $g_1$ are proper convex functions and

Moreover, it is easy to see that $A=A^{cl}=[0,+\mathrm{\infty })$ and

Hence,

This implies that the (LSC) holds. However, the function g is not lsc at $x=0$.

The following proposition gives an equivalent condition to ensure that

in terms of the (LSC). For this purpose, we first give the following lemma by the definition of conjugate functions. The proof is standard (cf. [[14], Lemma 4.1]), and so we omit it.

Lemma 3.1 Let $p\in X^{\ast }$, and let $r\in \mathbb{R}$. Then the following statements hold:

Proposition 3.2 The family $\{f,g,{\delta }_C;f_t,g_t:t\in T\}$ satisfies the (LSC) if and only if (3.16) holds. Consequently, if the (LSC) holds, then the weak Lagrange duality holds.

Proof Suppose that the (LSC) holds. Then (3.14) holds. Let $p\in X^{\ast }$. To show that $v(P_p)=v(P_p^{cl})$, it suffices to show that $v(P_p)\ge v(P_p^{cl})$ by (3.10). To do this, suppose, on the contrary, that $v(P_p)<v(P_p^{cl})$. Then there exists $r\in \mathbb{R}$ such that $v(P_p)<-r<v(P_p^{cl})$. Thus, by (3.18), $(p,r)\in epi{(f-clg+{\delta }_{A^{cl}})}^{\ast }$, and so $(p,r)\in epi{(f-g+{\delta }_A)}^{\ast }$ by (3.14). It follows from (3.17) that $v(P_p)\ge -r$. This contradicts $v(P_p)<-r$ and completes the proof of the inequality $v(P_p)\ge v(P_p^{cl})$.

Conversely, suppose that (3.16) holds. By Remark 3.1(b), it suffices to show that (3.15) holds. To do this, let $(p,r)\in epi{(f-clg+{\delta }_{A^{cl}})}^{\ast }$. Then, by (3.18), $v(P_p^{cl})\ge -r$, and so $v(P_p)\ge -r$, thanks to (3.16). Hence, by (3.17), $(p,r)\in epi{(f-g+{\delta }_A)}^{\ast }$. Therefore, (3.15) is proved. The proof is complete. □

The remainder of this paper is devoted to studying the stable total Lagrange duality between $(P)$ and $(D)$. For each $x\in X$, let $T(x)$ be the active index set of system (3.1), that is,

For simplicity, we define $N^{\prime }(x)$ by

and $N_0^{\prime }(x)$ by

where, following [[25], p.2], we adapt the convention that ${\bigcap }_{t\in \mathrm{\varnothing }}{S}_t=X$. Then for each $x\in X$,

The following proposition provides an estimate for the subdifferential of the DC function $f-g+{\delta }_A$ in terms of the subdifferentials of the convex functions involved.

Proposition 3.3 Suppose that the family $\{f,g,{\delta }_C;f_t,g_t:t\in T\}$ satisfies the (LSC). Then for each $x_0\in {\mathrm{\Omega }}_0$,

Proof Let $x_0\in {\mathrm{\Omega }}_0$ and $p\in N^{\prime }(x_0)$. Then there exists $\lambda \in {\mathbb{R}}_{+}^{(T)}$ such that for each $(u^{\ast },v^{\ast })\in H^{\ast }$,

Let $x\in X$. Then for each $(u^{\ast },v^{\ast })\in H^{\ast }$,

hence,

Taking the infimum over $H^{\ast }$, we get that

Since $x_0\in {\mathrm{\Omega }}_0$, it follows from (2.9) that $(clg)(x_0)=g(x_0)$ and $(cl{g}_t)(x_0)=g_t(x_0)$ for each $t\in T$. Note that $x_0\in A^{cl}$ and $f_t(x_0)-g_t(x_0)=0$ for each $t\in T(x_0)$. Then, by (3.22), one has that for each $x\in X$,

Hence,

Moreover, by Proposition 3.2, the (LSC) implies that $v(P_p^{cl})=v(P_p)$. This together with (3.23) implies that for each $x\in X$,

Hence, $p\in \partial (f-g+{\delta }_A)(x_0)$, and inclusion (3.21) holds. □

Considering the possible inclusions among $\partial (f-g+{\delta }_A)(x)$, $N^{\prime }(x)$ and $N_0^{\prime }(x)$, we introduce the following definition.

Definition 3.3 The family $\{f,g,{\delta }_C;f_t,g_t:t\in T\}$ is said to satisfy

1. (a)

   the quasi weakly basic constraint qualification (the quasi (WBCQ)) at $x\in A$ if

   $$\partial (f-g+{\delta }_A)(x)\subseteq N_0^{\prime }(x);$$

   (3.24)
2. (b)

   the weakly basic constraint qualification (the (WBCQ)) at $x\in A$ if

   $$\partial (f-g+{\delta }_A)(x)\subseteq N^{\prime }(x).$$

   (3.25)

We say that the family $\{f,g,{\delta }_C;f_t,g_t:t\in T\}$ satisfies the quasi (WBCQ) (resp. the (WBCQ)) if it satisfies the quasi (WBCQ) (resp. the (WBCQ)) at each point $x\in A$.

Remark 3.2

1. (a)

   The following implication holds:

   $$\text{the (WBCQ)}⟹\text{the quasi (WBCQ)}.$$
2. (b)

   In the special case, when $g=g_t=0$, $t\in T$, the quasi (WBCQ) and (WBCQ) are reduced to the (WBCQ) _f for the family $\{{\delta }_C;f_t:t\in T\}$ introduced in [6].

For our main theorems in this section, the following lemma is helpful.

Lemma 3.2 Let $x_0\in X$ and $p\in X^{\ast }$ with $x_0\in S(P_p)$. If $p\in N^{\prime }(x_0)$, then there exists $\overline{\lambda }\in {\mathbb{R}}_{+}^{(T)}$ such that for each $w^{\ast }=(u^{\ast },v^{\ast })\in H^{\ast }$,

Proof Let $p\in N^{\prime }(x_0)$. Then there exists $\overline{\lambda }={({\overline{\lambda }}_t)}_{t\in T}\in {\mathbb{R}}_{+}^{(T)}$ with

such that for each $(u^{\ast },v^{\ast })\in H^{\ast }$,

Let $(u^{\ast },v^{\ast })\in H^{\ast }$. Then there exists $x^{\ast }\in \partial (f+{\delta }_C+{\sum }_{t\in T}{\overline{\lambda }}_t{f}_t)(x_0)$ such that

By the Young equality (2.6),

and by the Young-Fenchel inequality (2.3),

Combining (3.28), (3.29) with (3.30), we have

where the last equality holds because of (3.27) and $x_0\in A$. Since $x_0\in S(P_p)$, it follows that (3.26) holds. The proof is complete. □

The following theorem provides a sufficient condition and a necessary condition for the stable ${\mathrm{\Omega }}_0$-total Lagrange duality.

Theorem 3.1 Consider the following assertions:

1. (i)

   The family $\{f,g,{\delta }_C;f_t,g_t:t\in T\}$ satisfies the (WBCQ).

2. (ii)

   The stable ${\mathrm{\Omega }}_0$-total Lagrange duality holds between $(P)$ and $(D)$.

3. (iii)

   The family $\{f,g,{\delta }_C;f_t,g_t:t\in T\}$ satisfies the quasi (WBCQ).

Then (i) ⇒ (ii) ⇒ (iii).

Proof (i) ⇒ (ii) Suppose that (i) holds. Let $p\in X^{\ast }$ be such that $S(P_p)\cap {\mathrm{\Omega }}_0\ne \mathrm{\varnothing }$. Take $x_0\in S(P_p)\cap {\mathrm{\Omega }}_0$. Then

thanks to the assumed (WBCQ). Thus, by Lemma 3.2, we get that there exists $\overline{\lambda }\in {\mathbb{R}}_{+}^{(T)}$ such that (3.26) holds for each $w^{\ast }=(u^{\ast },v^{\ast })\in H^{\ast }$. Moreover, we have that $v(P_p)\ge v(D_p)$ by Corollary 3.1. Thus, $v(D_p)=v(P_p)$ and $\overline{\lambda }$ is an optimal solution of $(D_p)$. This implies that the stable ${\mathrm{\Omega }}_0$-total Lagrange duality holds.

(ii) ⇒ (iii) Suppose that (ii) holds. Let $x_0\in A$. Obviously, if $\partial H(x_0)=\mathrm{\varnothing }$, then the quasi (WBCQ) holds trivially because $N_0^{\prime }(x_0)=X^{\ast }$. Below, we assume that $\partial H(x_0)\ne \mathrm{\varnothing }$. Let $p\in \partial (f-g+{\delta }_A)(x_0)$. Then by (3.13), we have that $x_0\in S(P_p)$, and hence $x_0\in S(P_p)\cap {\mathrm{\Omega }}_0$. By the assumed ${\mathrm{\Omega }}_0$-total Lagrange duality, there exists $\overline{\lambda }={(\overline{\lambda })}_{t\in T}\in {\mathbb{R}}_{+}^{(T)}$ such that for each $(u^{\ast },v^{\ast })\in \partial H(x_0)$,

Noting that $v(P_p)=f(x_0)-g(x_0)-〈p,x_0〉$, we have

Since by the Young-Fenchel inequality (2.3),

and by the Young equality (2.6),

it follows that

where the last inequality holds because $x_0\in A$. Thus,

Moreover, by (3.31) and (3.32), we have