Slater's condition

In mathematics, Slater's condition (or Slater condition) is a sufficient condition for strong duality to hold for a convex optimization problem, named after Morton L. Slater.^[1] Informally, Slater's condition states that the feasible region must have an interior point (see technical details below). Slater's condition is a specific example of a constraint qualification.^[2] In particular, if Slater's condition holds for the primal problem, then the duality gap is 0, and if the dual value is finite then it is attained.

Formulation

Let $f_{1}, \dots, f_{m}$ be real-valued functions on some subset $D$ of $ℝ^{n}$ . We say that the functions satisfy the Slater condition if there exists some $x$ in the relative interior of $D$ , for which $f_{i} (x) < 0$ for all $i$ in $1, \dots, m$ . We say that the functions satisfy the relaxed Slater condition if:^[3]

Some $k$ functions (say $f_{1}, \dots, f_{k}$ ) are affine;
There exists $x \in relint D$ such that $f_{i} (x) \leq 0$ for all $i = 1, \dots, k$ , and $f_{i} (x) < 0$ for all $i = k + 1, \dots, m$ .

Application to convex optimization

Consider the optimization problem

Minimize f_{0} (x)

subject to:

f_{i} (x) \leq 0, i = 1, \dots, m

A x = b

where $f_{0}, \dots, f_{m}$ are convex functions. This is an instance of convex programming. Slater's condition for convex programming states that there exists an $x^{*}$ that is strictly feasible, that is, all m constraints are satisfied, and the nonlinear constraints are satisfied with strict inequalities. If a convex program satisfies Slater's condition (or relaxed condition), and it is bounded from below, then strong duality holds. Mathematically, this states that strong duality holds if there exists an $x^{*} \in relint (D)$ (where relint denotes the relative interior of the convex set $D : = \cap_{i = 0}^{m} dom (f_{i})$ ) such that

f_{i} (x^{*}) < 0, i = 1, \dots, m,

(the convex, nonlinear constraints)

A x^{*} = b .

^[4]

Generalized Inequalities

Given the problem

Minimize f_{0} (x)

subject to:

f_{i} (x) \leq_{K_{i}} 0, i = 1, \dots, m

A x = b

where $f_{0}$ is convex and $f_{i}$ is $K_{i}$ -convex for each $i$ . Then Slater's condition says that if there exists an $x^{*} \in relint (D)$ such that

f_{i} (x^{*}) <_{K_{i}} 0, i = 1, \dots, m

and

A x^{*} = b

then strong duality holds.^[4]

References

↑ Slater, Morton (1950). Lagrange Multipliers Revisited (PDF). Cowles Commission Discussion Paper No. 403 (Report). Reprinted in Giorgi, Giorgio; Kjeldsen, Tinne Hoff, eds. (2014). Traces and Emergence of Nonlinear Programming. Basel: Birkhäuser. pp. 293–306. ISBN 978-3-0348-0438-7.
↑ Takayama, Akira (1985). Mathematical Economics. New York: Cambridge University Press. pp. 66–76. ISBN 0-521-25707-7.
↑ Nemirovsky and Ben-Tal (2023). "Optimization III: Convex Optimization" (PDF).
↑ ^4.0 ^4.1 Boyd, Stephen; Vandenberghe, Lieven (2004). Convex Optimization (pdf). Cambridge University Press. ISBN 978-0-521-83378-3. Retrieved October 3, 2011.

[1] Slater, Morton (1950). Lagrange Multipliers Revisited (PDF). Cowles Commission Discussion Paper No. 403 (Report). Reprinted in Giorgi, Giorgio; Kjeldsen, Tinne Hoff, eds. (2014). Traces and Emergence of Nonlinear Programming. Basel: Birkhäuser. pp. 293–306. ISBN 978-3-0348-0438-7.

[2] Takayama, Akira (1985). Mathematical Economics. New York: Cambridge University Press. pp. 66–76. ISBN 0-521-25707-7.

[3] Nemirovsky and Ben-Tal (2023). "Optimization III: Convex Optimization" (PDF).

[boyd-4] 4.0 ^4.1 Boyd, Stephen; Vandenberghe, Lieven (2004). Convex Optimization (pdf). Cambridge University Press. ISBN 978-0-521-83378-3. Retrieved October 3, 2011.

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[2]

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Slater's condition

Contents

Formulation

Application to convex optimization

Generalized Inequalities

See also

References

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