MAXIMA, MINIMA AND SADDLE POINTS FOR FUNCTIONS OF TWO VARIABLES 363G
zxyFigure 36.11
Substituting in equation (2) gives:
S=xy+ 2 y(
62. 5
xy)
+ 2 x(
62. 5
xy)i.e. S=xy+125
x+125
y
which is a function of two variables∂s
∂x=y−125
x^2=0 for a stationary point,hence x^2 y= 125 (3)
∂s
∂y=x−125
y^2=0 for a stationary point,hence xy^2 = 125 (4)
Dividing equation (3) by (4) gives:
x^2 y
xy^2=1, i.e.x
y=1, i.e.x=ySubstitutingy=xin equation (3) givesx^3 =125,
from which,x=5m.
Hencey=5 m also
From equation (1), (5) (5)z= 62. 5
from which, z=
62. 5
25= 2 .5m∂^2 S
∂x^2=250
x^3,∂^2 S
∂y^2=250
y^3and∂^2 S
∂x∂y= 1Whenx=y=5,∂^2 S
∂x^2=2,∂^2 S
∂y^2=2 and∂^2 S
∂x∂y= 1=(1)^2 −(2)(2)=− 3Since<0 and∂^2 S
∂x^2>0, then the surface areaSis
aminimum.Hence the minimum dimensions of the container to
have a volume of 62.5 m^3 are5 m by 5 m by 2.5 m.
From equation (2),minimum surface area,S=(5)(5)+2(5)(2.5)+2(5)(2.5)
=75 m^2Now try the following exercise.Exercise 145 Further problems on maxima,
minima and saddle points for functions of two
variables- The functionz=x^2 +y^2 +xy+ 4 x− 4 y+ 3
has one stationary value. Determine its co-
ordinates and its nature.
[Minimum at (−4, 4)]- An open rectangular container is to have a
volume of 32 m^3. Determine the dimensions
and the total surface area such that the total
surface area is a minimum.
[
4mby4mby2m,
surface area=48m^2
]- Determine the stationary values of the
function
f(x,y)=x^4 + 4 x^2 y^2 − 2 x^2 + 2 y^2 − 1and distinguish between them.
[
Minimum at (1, 0),
minimum at (−1, 0),
saddle point at (0, 0)]- Determine the stationary points of the sur-
facef(x,y)=x^3 − 6 x^2 −y^2.
[
Maximum at (0, 0),
saddle point at (4, 0)
]