Answer:
1) There is only a critical point at (3,3).
2) If there is a local minimum, the value of the discriminant must be D>0
3) If there is a local maximum, the value of the discriminant must be D>0
4) If there is a saddle point, the value of the discriminant must be D<0
5) There is not a local maximum of f
6) There is a local minimum at (3,3). f(3,3)=23
Step-by-step explanation:
We have the fuction:
[tex]f(x,y)=x^2+y^2-6x-6y+41[/tex]
Its partial derivatives are:
[tex]f_x=2x-6[/tex]
[tex]f_y=2y-6[/tex]
When [tex]f_x=0[/tex]
0=2x-6 ⇒ 2x=6 ⇒x=3
When [tex]f_y=0[/tex]
0=2y-6 ⇒ 2y=6 ⇒y=3
The critical point is (3,3)
Its second order derivatives are:
[tex]f_{xx}=2[/tex]
[tex]f_{yy}=2[/tex]
[tex]f_{xy}=0[/tex]
The value of the discriminant is
[tex]D=f_{xx} \times f_{yy}-(f_{xy})^2[/tex]=2×2-0=4
As D>0 and [tex]f_{xx}>0[/tex], there is a local minimun at (3,3)
The value of f(x,y) at (3,3) is:
[tex]f(x,y)=x^2+y^2-6x-6y+41=3^2+3^2-6\times3-6\times3+41=9+9-18-18+41=23[/tex]
