Differentiating composite functions using the chain rule.

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OBJECTIVES:
1. Find the derivative of a composite function using the Chain Rule.
2. Find the derivative of a function using the General Power Rule.
3. Simplify the derivative of a function using algebra.
4. Find the derivative of a trigonometric function using the Chain Rule.
1. Differentiation
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2. The Chain Rule
Copyright © Cengage Learning. All rights reserved.
3.  Find the derivative of a composite function using the
Chain Rule.
 Find the derivative of a function using the General
Power Rule.
 Simplify the derivative of a function using algebra.
 Find the derivative of a trigonometric function using the
Chain Rule.
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4. The Chain Rule
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5. The Chain Rule
We have yet to discuss one of the most powerful
differentiation rules—the Chain Rule.
This rule deals with composite functions and adds a
surprising versatility to the rules discussed in the two
previous sections.
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6. The Chain Rule
For example, compare the functions shown below.
Those on the left can be differentiated without the Chain
Rule, and those on the right are best differentiated with the
Chain Rule.
Basically, the Chain Rule states that if y changes dy/du
times as fast as u, and u changes du/dx times as fast as x,
then y changes (dy/du)(du/dx) times as fast as x.
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7. Example 1 – The Derivative of a Composite Function
A set of gears is constructed, as shown in Figure 2.24,
such that the second and third gears are on the same axle.
As the first axle revolves, it drives the
second axle, which in turn drives the
third axle.
Let y, u, and x represent the numbers
of revolutions per minute of the first,
second, and third axles, respectively.
Find dy/du, du/dx, and dy/dx ,and
show that
Figure 2.24
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8. Example 1 – Solution
Because the circumference of the second gear is three
times that of the first, the first axle must make three
revolutions to turn the second axle once.
Similarly, the second axle must make two revolutions to
turn the third axle once, and you can write
Combining these two results, you know that the first axle
must make six revolutions to turn the third axle once.
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9. Example 1 – Solution cont’d
So, you can write
In other words, the rate of change of y with respect to x is
the product of the rate of change of y with respect to u and
the rate of change of u with respect to x. 9
10. The Chain Rule
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11. The Chain Rule
When applying the Chain Rule, it is helpful to think of the
composite function f ◦ g as having two parts– an inner part
and an outer part.
The derivative of y = f (u) is the derivative of the outer
function (at the inner function u) times the derivative of the
inner function.
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12. Example 2 – Decomposition of a Composite Function
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13. The General Power Rule
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14. The General Power Rule
The function y = [u(x)]n is one of the most common types of
composite functions.
The rule for differentiating such functions is called the
General Power Rule, and it is a special case of the Chain
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15. The General Power Rule
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16. Example 4 – Applying the General Power Rule
Find the derivative of f(x) = (3x – 2x2)3.
Let u = 3x – 2x2.
Then f(x) = (3x – 2x2)3 = u3
and, by the General Power Rule, the derivative is
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17. Simplifying Derivatives
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18. Simplifying Derivatives
The next three examples illustrate some techniques for
simplifying the “raw derivatives” of functions involving
products, quotients, and composites.
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19. Example 7 – Simplifying by Factoring Out the Least Powers
Find the derivative of
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20. Example 8 – Simplifying the Derivative of a Quotient
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21. Example 9 – Simplifying the Derivative of a Power
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22. Trigonometric Functions and the
Chain Rule
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23. Trigonometric Functions and the Chain Rule
The “Chain Rule versions” of the derivatives of the six
trigonometric functions are as follows.
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24. Example 10 – The Chain Rule and Trigonometric Functions
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25. Trigonometric Functions and the Chain Rule
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