AP Calculus Ms. Kohler
3.5A Derivatives Rules for the Sine and Cosine Functions
Use your calculator to graph the numerical derivative of [pic].
What new function do you see? Complete your derivative rule below for the sine function.
Now graph the numerical derivative of [pic].
What new function do you see? Complete your derivative rule for the cosine function.
[pic] [pic]
Practice:
1. Find the derivative function for [pic]
2. Write the equation of the tangent and normal line to [pic]
3.5B Rules for the Tangent, Cotangent, Secant, and Cosecant Functions
The remaining trigonometry function derivatives can be derived from their definitions.
[pic]
[pic]
[pic]
[pic]
Practice:
1. Verify the derivative of the tangent and secant functions.
Find the derivative for each:
2. [pic] 3. [pic]
3.6A The CHAIN RULE for Derivatives
Many functions are composites where [pic] is the outer function and [pic] is the inner function of [pic].
[pic]
The derivative process for these is called the CHAIN RULE:
“The derivative of the outer function[pic] with respect to [pic]
TIMES the derivative of the inner function [pic].”
Practice: Find the derivative function for each.
1. [pic] where [pic] 2. [pic] where [pic]
3. [pic]
3.6B The CHAIN RULE … more practice
This rule can be extended … if a function is a composite of more than two functions such as
[pic] , then [pic]
Often, you need to REWRITE the function to identify the order from the outside in.
Practice: Find the derivative function for each.
1. [pic] 2. [pic] 3. [pic]
3.6C The CHAIN RULE and Symbolic Manipulation
The table shows selected values of functions [pic] and [pic] along with the derivatives at these locations.
|[pic] |[pic] |[pic] |[pic] |[pic] |
| 0 |1 |1 |5 |1/3 |
|1 |3 |( 4 |( 1/3 |( 8/3 |
For each function described below, determine
the value of its derivative at the given x-value.
1. [pic]
2. [pic]
3.
4.
3.7A The Implicit Differentiation Method
Some curves like [pic] cannot be written explicitly as a function of [pic]. (p. 157)
This is an example of an Implicitly Defined Curve. Often, these are the union of 2 or more functions.
To find the derivative of this type of curve,
Treat [pic] as some differentiable function of [pic] (that we cannot determine) & use the chain rule.
• Differentiate each term in the equation with respect to [pic].
• Collect terms with [pic] on one side of the equation; move others to the opposite side.
• Factor out [pic], then solve the equation for [pic].
• This result is a formula for the slope of the curve at any point [pic] on the graph.
Practice: Find the derivative of each.
1. [pic] 2. [pic] 3. [pic]
3.7B Implicit Differentiation … more
1. Find [pic] for the implicitly defined curve on p. 157: [pic]
2. Write the equations for the lines tangent and normal to the curve [pic] at [pic] .
3. Find [pic] for the curve [pic]
Summary of Derivatives so far … these all have the chain rule built in!
c is a constant; u and v are differentiable functions of x.
Basics:
[pic]
the POWER Rule :
[pic]
the CHAIN Rule :
the PRODUCT Rule :
[pic]
the QUOTIENT Rule :
[pic]
TRIG Derivatives :
[pic]
[pic]
[pic]
[pic]
[pic]
3.8A Inverse Function Derivatives A Self-Guided Lesson
Review Inverse Function Properties on p. 37 – 39, then answer the following prompts.
1. What types of functions will always have an inverse?
2. What is the definition of a one-to-one function?
3. What symbol is used for the inverse of [pic]? ____________
4. Describe how to create the inverse function equation from the original [pic] equation.
5. Describe the relationship between the graphs of [pic] and its inverse function.
6. The domain of [pic] is the ______________ of the inverse function.
The range of [pic] is the ______________ of the inverse function.
7. Describe the algebraic test used to verify that [pic] and [pic] are inverses.
Derivatives (slopes) of a Function and its Inverse Function
Page 165: Study the graphs of figure 3.52. For any point on [pic] and its corresponding point on the inverse [pic], how are the slopes of the tangent lines to these functions related?
3.8B Derivatives of INVERSE TRIG Functions
[pic] [pic] [pic]
If u is a differentiable function of x,
[pic] [pic] [pic]
Practice: Find the derivative of each with the triangle method … verify with the formula.
1. [pic] 2. [pic]
These are very obscure … very rarely used ...
[pic] [pic] [pic]
3.9A Exponential and Logarithmic Functions … Base e
[pic]
• Graph [pic] and its numerical derivative in bold. What does the derivative function look like?
• Graph the inverse [pic] and its numerical derivative. What function does this look like?
In General, given that [pic] is a differentiable function of [pic], we now have two more derivative rules:
[pic] and [pic]
Practice: Find each derivative function. State the domain if there are restrictions.
1. [pic]
2. [pic]
3. [pic]
4. [pic]
3.9B NON - Base e Functions
Recall all the LOG RULES: [pic], [pic], [pic]
[pic] [pic] [pic]
Suppose [pic] is some NON - e positive base and [pic] is a differentiable function of [pic], then
and
Practice: Find each derivative. State the domain if there are restrictions.
1. [pic]
2. [pic]
3. [pic]
4. [pic]
-----------------------
[pic]
[pic]
[pic]
[pic]
[pic]
[pic]
[pic]
[pic]
[pic]
[pic]
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