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Economics 214

Economics 214. Lecture 38 Constrained Optimization. Interpreting Lagrange Multiplier. With our Lagrangian function, we have a new variable, , the Lagrange multiplier.

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Economics 214

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  1. Economics 214 Lecture 38 Constrained Optimization

  2. Interpreting Lagrange Multiplier • With our Lagrangian function, we have a new variable, , the Lagrange multiplier. • The Lagrange multiplier, , represents the effect of a small change in the constraint on the optimal value of the objective function.

  3. Proof of Interpretation

  4. Proof Continued.

  5. Utility Max Example

  6. Interpreting the Lagrange Multiplier In other contexts, the Lagrange multiplier may be interpreted differently. For example, if the objective function represents the profit function from undertaking an activity and the constraint reflects a limit on using an input to that activity, the Lagrange multiplier reflects the marginal benefit from having additional input. In this case the Lagrange multiplier represents the price a firm would be willing to pay per unit of additional input, which is known as the shadow price of the input.

  7. Figure 11.3 Short-Run Cost and Long-Run Cost Functions

  8. Envelope Theorem

  9. Envelope Theorem Continued

  10. Envelope Theorem Continued

  11. Envelope Theorem Conclusion • The envelope theorem shows that the effect of a small change in a parameter of a constrained optimization problem on its maximum value can be determined by considering only the partial derivative of the objective function and the partial derivative of the constraint with respect to that parameter. • To a first approximation, it is not necessary to consider how a small change in a parameter affects the optimal value of the variables of the problem in order to evaluate the change in its maximum value.

  12. Average Cost Curves

  13. Average Cost Function cont.

  14. Figure 11.3 Short-Run Cost and Long-Run Cost Functions

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