Transcript Document

2.6 Related Rates
Don’t get
Related rate problems are differentiated with
respect to time. So, every variable, except t is
differentiated implicitly.
Ex. Two rates that are related.
Given y = x2 + 3, find dy/dt when x = 1, given
that dx/dt = 2.
y = x2 + 3
dy
dx Now, when x = 1 and dx/dt = 2, we
 2x
dt
dt have
dy
 2(1)( 2)  4
dt
Procedure For Solving
Related Rate Problems
1. Assign symbols to all given quantities and
quantities to be determined. Make a sketch
and label the quantities if feasible.
2. Write an equation involving the variables
whose rates of change either are given or are
to be determined.
3. Using the Chain Rule, implicitly differentiate
both sides of the equation with respect to t.
4. Substitute into the resulting equation all known
values for the variables and their rates of change.
Solve for the required rate of change.
Ex. A pebble is dropped into a calm pond, causing
ripples in the form of concentric circles. The radius
r of the outer ripple is increasing at a constant rate
of 1 foot per second. When this radius is 4 ft., what
rate is the total area A of the disturbed water
increasing.
Givens:
dr
 1 when
dt
Given equation:
Differentiate:
r4
A  r
dA
?
dt
2
dA
dr
 2r
dt
dt
dA
 2 14 
dt
 8
An inflating balloon
Air is being pumped into a spherical balloon at the
rate of 4.5 in3 per second. Find the rate of change
of the radius when the radius is 2 inches.
Given: dV
 4.5in 3 / sec
dt
4 3
Equation: V  r
3
Diff.
& Solve:
dr
r = 2 in. Find :
?
dt
dV
2 dr
 4r
dt
dt
dr
4.5  4 2
dt
2
dr
.09in /sec 
dt
The velocity of an airplane tracked by radar
An airplane is flying at an elevation of 6 miles on a flight
path that will take it directly over a radar tracking station.
Let s represent the distance (in miles)between the radar
station and the plane. If s is decreasing at a rate of 400
miles per hour when s is 10 miles, what is the velocity of
the plane.
s
6
x
ds
 400
dt
Given:
s  10
Find:
dx
?
dt
Equation:
x2 + 62 = s2
Solve:
dx
ds
2x
 2s
dt
dt
To find dx/dt, we
must first find x
when s = 10
x  s  36  100 36  8
2
dx
28  210  400 
dt
Day 1
dx
 500 mph
dt
A fish is reeled in at a rate of 1 foot per second
from a bridge 15 ft. above the water. At what
rate is the angle between the line and the water
changing when there is 25 ft. of line out?
x
15 ft.

dx
 1
Given:
x = 25 ft. h = 15 ft.
dt
d
Find:
?
dt
Equation:
15
1
sin


15
x
sin  
x
Solve:
d
 2 dx
cos    15 x
dt
dt
d
 15 dx
 2
dt x cos  dt
d

dt
 15
 1
2  20 
25  
 25 
d
3

rad / sec
dt 100
Ex. A pebble is dropped into a calm pond, causing
ripples in the form of concentric circles. The radius
r of the outer ripple in increasing at a constant rate
of 1 foot per second. When this radius is 4 ft., what
rate is the total area A of the disturbed water
increasing.
An inflating balloon
Air is being pumped into a spherical balloon at the
rate of 4.5 in3 per minute. Find the rate of change
of the radius when the radius is 2 inches.