Author: Hannah Seo (ChE 345, Spring 2015)
Steward: Dajun Yue, Fengqi You
Lagrangian duality theory refers to a way to find a bound or solve an optimization problem (the primal problem) by looking at a different optimization problem (the dual problem). More specifically, the solution to the dual problem can provide the lower bound to the primal problem or provide the same optimal solution as the primal problem, which is useful if the primal problem is harder to solve than the dual problem.
General Lagrange Dual Problem
Consider the following optimization problem in standard form:
The Lagrangian is given by:
where are Lagrange multipliers associated with , and are Lagrange multipliers associated with .
Then the Lagrange dual function is .
The Lagrange dual problem is:
Weak and Strong Duality Theorem
The weak duality theorem says that for the general problem, the optimal value of the Lagrange dual problem () and the optimal value of the primal problem () are related by:
This means that the dual problem provides the lower bound for the primal problem. The difference between the two optimal values is called the optimal duality gap.
The strong duality theorem says that for convex problems that satisfy certain conditions, the optimal duality gap is zero, meaning that the optimal values of the primal and dual problems are the same. For convex problems to guarantee the strong duality condition, Slater's constraint qualifications must be met, meaning that a convex problem must be strictly feasible.
Assuming that strong duality holds, is the optimal solution of the primal problem, and are the optimal values of the dual problem, then
Special Case: Linear Programming Problem
For linear programming problems, the construction of the dual problem is much simpler. The feasible solutions for the primal problem yield bounds on the optimal objective function value on the dual problem and vice versa.
Given the primal problem:
the corresponding dual problem is:
Real world applications that utilize Lagrangean duality theory include resource allocation problems, models of electrical networks, and models of economic markets.
In the resource allocation problem, the primal problem is the problem as seen by the production manager, while the dual problem is the problem as seen by the supplier. Both problems are linear programming problems, so the strong duality theorem applies. Thus, using the solutions to the two problems, the production levels and prices can be set to establish equilibrium.
For models of electrical networks, the current flows can be represented as the primal variables and the voltage differences can be seen as the dual variables. This representation allows for the optimization of electrical networks.
For models of economic markets, the production and consumption levels are the primal variables and the prices of goods and services can be seen as the dual variables.
Utilization of the principle of Lagrangean duality can be useful for problems that are hard to solve. By looking at the problem from a different perspective by transforming the original problem, the resulting problem may give a solution that is the bound to the original problem or is the same as the solution to the original problem.
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