3.7 applications of tangent lines

Applications of Tangent Lines
In this section we look at two applications of the
tangent lines.

tangent lines.
Differentials and Linear Approximation

tangent lines.
Let f(x) = x2 be as shown. y
Its derivative f '(x) = dy = 2x.
dx
y = x2
x

tangent lines.
Its derivative f '(x) = = 2x.
dy
dx
The slope at the point (3,9)
is f '(3) = 6.
(3,9)
y = x2
x

tangent lines.
dy
dx
is f '(3) = 6.
(3,9)
y = x2
y = 6x – 9
Hence the tangent line at (3, 9) is
y = 6(x – 3) + 9 or y = 6x – 9.
x

tangent lines.
dy
dx
is f '(3) = 6.
(3,9)
y = x2
y = 6x – 9
Hence the tangent line at (3, 9) is
y = 6(x – 3) + 9 or y = 6x – 9.
Note that in the notation we write
that
dx
dy
dx
= 6
x = 3
dy
dx
= f '(a)
x = a
dy
where in general
x

In general the tangent line
at x = a, i.e. at (a, f(a)), is
T(x) = f'(a)(x – a) + f(a)
with f'(a) = dy
dx
x = a
tangent line
T(x) = f'(a)(x – a) + f(a)
(a,f(a))
y = f(x)
x

T(x) = f'(a)(x – a) + f(a)
with f'(a) = dy
dx
x = a
tangent line
T(x) = f'(a)(x – a) + f(a)
(a,f(a))
y = f(x)
x
For any x value that is near the
point x = a, say x = b, the
function–values f(b) and T(b) are
near each other,
(a,f(a))
T(x) = y
(b,f(b))
(b,T(b))
y = f(x)

T(x) = f'(a)(x – a) + f(a)
with f'(a) = dy
dx
x = a
tangent line
T(x) = f'(a)(x – a) + f(a)
(a,f(a))
y = f(x)
x
near each other,
(a,f(a))
T(x) = y
(b,f(b))
(b,T(b))
y = f(x)
f(b)

T(x) = f'(a)(x – a) + f(a)
with f'(a) = dy
dx
x = a
tangent line
T(x) = f'(a)(x – a) + f(a)
(a,f(a))
y = f(x)
x
near each other,
(a,f(a))
T(x) = y
(b,f(b))
(b,T(b))
y = f(x)
f(b) T(b)

T(x) = f'(a)(x – a) + f(a)
with f'(a) = dy
dx
x = a
tangent line
T(x) = f'(a)(x – a) + f(a)
(a,f(a))
y = f(x)
x
near each other, hence we may
use T(b) as an estimation for f(b),
(a,f(a))
T(x) = y
(b,f(b))
(b,T(b))
y = f(x)
f(b) T(b)

T(x) = f'(a)(x – a) + f(a)
with f'(a) = dy
dx
x = a
tangent line
T(x) = f'(a)(x – a) + f(a)
(a,f(a))
y = f(x)
x
near each other, hence we may
use T(b) as an estimation for f(b),
since T(x) is a linear function
and most likely it’s easier to
calculate T(b) than f(b).
(a,f(a))
T(x) = y
(b,f(b))
(b,T(b))
y = f(x)
f(b) T(b)

There are two ways to find T(b).

1. Find T(x) and evaluate T(b) directly.

1. Find T(x) and evaluate T(b) directly. For example,
the tangent line of y = sin(x) at x = 0 is T(x) = x,

hence for small x’s that are near 0, sin(x) ≈ x.
(Remember that x must be in radian measurements).

(a,f(a))
(x. T(x))
(b,f(b))
(b,T(b))
y = f(x)
x=a x=b
2. Find ΔT first and ΔT + f(a) = T(b).

(a,f(a))
(x. T(x))
(b,f(b))
(b,T(b))
y = f(x)
x=a
ΔT
x=b

In practice, ΔT is denoted as dy, the y–differential,
which is identified with the dy in dy/dx.
(a,f(a))
(x. T(x))
(b,f(b))
(b,T(b))
y = f(x)
x=a
ΔT= dy
x=b

And we set the x–differential dx = Δx,
(a,f(a))
(x. T(x))
(b,f(b))
(b,T(b))
y = f(x)
x=a
Δx=dx
ΔT= dy
x=b

and as before Δy = f(b) – f(a). (a,f(a))
(x. T(x))
(b,f(b))
(b,T(b))
y = f(x)
x=a
Δx=dx
ΔT= dy
x=b
Δy

and as before Δy = f(b) – f(a).
These measurements are
shown here. It’s important to
(a,f(a))
(x. T(x))
(b,f(b))
(b,T(b))
y = f(x)
x=a
Δx=dx
ΔT= dy
x=b
Δy
“see” them because the
geometry is linked to the algebra.

(a,f(a))
(x. T(x))
(b,f(b))
(b,T(b))
y = f(x)
x=a
Δx=dx
ΔT= dy
x=b
Δy
dy
dx
The derivative notation is inherited from the
notation of slopes as ratios.
Δy
Δx

dy
dx
notation of slopes as ratios. Suppose that
= f '(a) Δy
= L (= lim ),
Δx0
(a,f(a))
(x. T(x))
(b,f(b))
(b,T(b))
y = f(x)
x=a
Δx=dx
ΔT= dy
x=b
Δy
dy
dx
x = a
Δx
Δy
Δx

dy
dx
= f '(a) Δy
= L (= lim ),
Δx0
then for Δx close to 0, (a,f(a))
Δy
Δx
(x. T(x))
(b,f(b))
(b,T(b))
y = f(x)
x=a
Δx=dx
ΔT= dy
x=b
Δy
dy
dx
x = a
Δx
≈ L = slope at (a, f(a))
Δy
Δx

dy
dx
= f '(a) Δy
= L (= lim ),
Δx0
dy
dx
x = a
Δy
Δx
(x. T(x))
(b,f(b))
(b,T(b))
y = f(x)
x=a
Δx=dx
ΔT= dy
x=b
Δy
Δy ≈ L(Δx)
Δx
≈ L = slope at (a, f(a)) so
Δy
Δx

= f '(a) Δy
= L (= lim ),
Δx0
dy
dx
x = a
Δx
Δy
Δx
(x. T(x))
(b,f(b))
(b,T(b))
y = f(x)
x=a
Δx=dx
ΔT= dy
x=b
Δy
Δy ≈ L(Δx) = L dx = dy
dy
dx
Δy
Δx

dy
dx
= f '(a) Δy
= L (= lim ),
Δx0
dy
dx
x = a
Δx
Δy
Δx
(x. T(x))
(b,f(b))
(b,T(b))
y = f(x)
x=a
Δx=dx
ΔT= dy
x=b
Δy
The accuracy of this approximation
may be formulated mathematically.
Δy
Δx

dy
dx
Δy
Δx
= f '(a) Δy
= L (= lim ),
Δx0
dy
dx
x = a
Δx
Δy
Δx
(x. T(x))
(b,f(b))
(b,T(b))
y = f(x)
x=a
Δx=dx
ΔT= dy
x=b
Δy
So what have we done?
We have clarified the meaning of dy and dx, and
made it legal to treat dy/dx as a fraction both
algebraically and geometrically.

dy
dx
Δy
Δx
= f '(a) Δy
= L (= lim ),
Δx0
dy
dx
x = a
Δx
Δy
Δx
(x. T(x))
(b,f(b))
(b,T(b))
y = f(x)
x=a
Δx=dx
ΔT= dy
x=b
Δy
So what have we done?
We have clarified the meaning of dy and dx, and
made it legal to treat dy/dx as a fraction both
algebraically and geometrically. To summarize, given
dy
dx
y = f(x) and = f '(x), then Δy ≈ dy = f '(x)dx.

Example A. Let y = f(x) = √x.
a. Find the general formula of dy in terms of dx.

dy
dx = f '(x) = ½ x–½

dy
dx = f '(x) = ½ x–½ or dy = ½ x–½ dx

dy
dx = f '(x) = ½ x–½ or dy = ½ x–½ dx
b. Find the specific dy in terms of dx when x = 4.

dy
dx = f '(x) = ½ x–½ or dy = ½ x–½ dx
When x = 4 we get that dy = ¼ dx.

dy
dx = f '(x) = ½ x–½ or dy = ½ x–½ dx
When x = 4 we get that dy = ¼ dx. (This says that for
small changes in x, the change in the output y is
approximate ¼ of the given change in x, at x = 4.)

dy
dx = f '(x) = ½ x–½ or dy = ½ x–½ dx
c. Given that Δx = dx = 0.01, find dy at x = 4.
Use the result to approximate √4.01.

dy
dx = f '(x) = ½ x–½ or dy = ½ x–½ dx
Given that Δx = dx = 0.01 and that dy = ¼ dx at x = 4,

dy
dx = f '(x) = ½ x–½ or dy = ½ x–½ dx
we have dy = ¼ (0.01) = 0.0025 ≈ Δy.

dy
dx = f '(x) = ½ x–½ or dy = ½ x–½ dx
we have dy = ¼ (0.01) = 0.0025 ≈ Δy.
Hence f(4 + 0.01) =√4.01 ≈ √4 + dy

dy
dx = f '(x) = ½ x–½ or dy = ½ x–½ dx
we have dy = ¼ (0.01) = 0.0025 ≈ Δy.
Hence f(4 + 0.01) =√4.01 ≈ √4 + dy = 4.0025.
(The calculator answer is 002498439..).

Your turn. Do the same at x = 9, and use the result to
approximate √8.995. What is the dx?

Hence we have the terms the “differentials” or
the “small differences” as opposed to the “differences”

and the symbols are dx and Δx respectively.

The differentials are used extensively in numerical
problems and the following is one example.

Newton’s Method for Approximating Roots

The Newton’s Method of approximating the location
of a root depends on the geometry of the tangent
line and the x–axis.

The Newton’s Method of approximating the location
of a root depends on the geometry of the tangent
line and the x–axis. If the geometry is right,
the successive x–intercepts of tangent–lines
approach a root not unlike a ball falls into a crevice.
We demonstrate this below.

y = f(x)
x = r
Suppose that we know there is a root in the shaded
region and we wish to calculate its location, and let’s
say it’s at x = r.

y = f(x)
x = r
x1
say it’s at x = r. We select a starting point x = x1 as
shown.

(x1,f(x1))
y = f(x)
x = r
x1
shown. Draw the tangent line at x1.

(x1,f(x1))
y = f(x)
x = r
x1 x2
shown. Draw the tangent line at x1. Let x2 be the
x–intercept of this tangent.

(x1,f(x1))
y = f(x)
x = r
(x2,f(x2))
x1 x3 x2
x–intercept of this tangent. Then we draw the tangent
line at x2, and let x3 be the x–intercept of the tangent
line at x2.

(x1,f(x1))
y = f(x)
x = r
(x2,f(x2))
(x3,f(x3))
x1 x3 x2
x–intercept of this tangent. Then we draw the tangent
line at x2, and let x3 be the x–intercept of the tangent
line at x2. Continuing in this manner, the sequence of
x’s is funneled toward the root x = r.

The successive intercepts may be calculated easily.
We give the formula here:
xn+1 = xn – f(xn)
f '(xn)

The successive intercepts may be calculated easily.
We give the formula here:
xn+1 = xn – f(xn)
f '(xn)
Example B.
Let y = f(x) = x3 – 3x2 – 5, its
graph is shown here. Assume
that we know that it has a root
between 2 < x < 5.
Starting with x1 = 4,
approximate this roots by the
Newton’s method to x3.
Compare this with a calculator
answer.
2 4
y
x
f(x) = x3 – 3x2 – 5

We have that f '(x) = 3x2 – 6x = 3x(x – 2)
2 x1=4
x
f(x) = x3 – 3x2 – 5
The geometry of the Newton’s Method
for example B.
Back to math–265 pg

x2 = x1 – f(x1)
f '(x1)
2 x1=4
x
f(x) = x3 – 3x2 – 5
for example B.
x2

x2 = x1 – f(x1)
f '(x1)
= 4 – f(4)
f '(4)
2 x1=4
x
f(x) = x3 – 3x2 – 5
for example B.
x2

x2 = x1 – f(x1)
f '(x1)
= 4 – f(4)
f '(4)
= 85/24
2 x1=4
x
f(x) = x3 – 3x2 – 5
≈ 3.542
for example B.
x2

x2 = x1 – f(x1)
f '(x1)
= 4 – f(4)
f '(4)
= 85/24
x3 = 85/24 –
f(85/24)
f '(85/24)
2 x1=4
x
f(x) = x3 – 3x2 – 5
≈ 3.542
x3 x2
for example B.

x2 = x1 – f(x1)
f '(x1)
= 4 – f(4)
f '(4)
= 85/24
x3 = 85/24 –
f(85/24)
f '(85/24)
≈ 3.432
2 x1=4
x
f(x) = x3 – 3x2 – 5
≈ 3.542
x3 x2
for example B.

x2 = x1 – f(x1)
f '(x1)
= 4 – f(4)
f '(4)
= 85/24
x3 = 85/24 –
f(85/24)
f '(85/24)
≈ 3.432
2 x1=4
x
f(x) = x3 – 3x2 – 5
≈ 3.542
x3 xThe software answer is 2
≈ 3.425988..
for example B.

3.7 applications of tangent lines

Recommandé

Recommandé

Contenu connexe

Tendances

Tendances (20)

En vedette

En vedette (20)

Similaire à 3.7 applications of tangent lines

Similaire à 3.7 applications of tangent lines (20)

Plus de math265

Plus de math265 (18)

Dernier

Dernier (20)

3.7 applications of tangent lines