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1. 2 Local maximum Local minimum 3 Saddle point.

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Presentation on theme: "1. 2 Local maximum Local minimum 3 Saddle point."— Presentation transcript:

1 1

2 2 Local maximum Local minimum

3 3 Saddle point

4 4 Given the problem of maximizing ( or minimizing) of the objective function: Z=f(x,y ) Finding the Stationary Values solutions of the following system:

5 1) Z=f(x,y)=x 2 +y 2 2) Z=f(x,y)=x 2 -y 2 3) Z=f(x,y)=xy 5

6 6 The Hessian Matrix H(x 0,y 0 )>0 f xx >0 minimum H(x 0,y 0 )>0 f x x <0 maximum H(x 0,y 0 )<0 saddle

7  The method of Lagrange multipliers provides a strategy for finding the maxima and minima of a function:  subject to constraints: 7

8 8

9 9

10 10 For instance minimize the objective function Subject to the constraint:

11  We can combine the constraint with the objective function:  Minimum in P(1/2;1/2) 11

12 12

13  We introduce a new variable ( λ ) called a Lagrange multiplier, and study the Lagrange function: 13

14 14

15 15

16 16 The point is a minimum The point is a maximum Bordered Hessian Matrix of the Second Order derivative is given by

17  Given the problem of maximizing ( or minimizing) of the objective function with constraints 17

18  We build a Lagrangian function :  Finding the Stationary Values: 18

19  Second order conditions:  We must check the sign of a Bordered Hessian: 19

20  n=2 e m=1  the Bordered Hessian Matrix of the Second Order derivative is given by  Det>0 imply Maximum  Det<0 imply Minimum 20

21 21

22  Case n=3 e m=1  : 22

23 23

24  n=3 e m=2  the matrix of the second order derivate is given by: 24

25 25

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