1. Calculus I (MAT 145) Dr. Day Wednesday March 20, 2019
Chapter 4: Using All Your Derivative Knowledge!
Absolute and Relative Extremes
What is a “critical number?”
Increasing and Decreasing Behavior of Functions
Connecting f and f’
Concavity of Functions: A function’s curvature
Connecting f and f”
Graphing a Function: Putting it All together!
Max-Mins Problems: Determine Solutions for Contextual Situations
Other Applications
Finally What if We Reverse the Derivative Process?
Return Quiz #8

2. Absolute (Global) Extrema
In the graph, the Absolute (Global) Maximum is 5 (y-value) and is found at x = 3.
The value 5 is the greatest value of the
function over its entire domain [1,7].
The Absolute (Global) Minimum is 2
and is found at x = 6.
The value 2 is the least value of the
Monday, March 18, 2019
MAT 145

3. Absolute Extrema
What is the absolute maximum in the graph? (This means “Tell me the greatest y-value.”)
Where is the absolute maximum located?
(This means, “Tell me the x-value that
corresponds to the maximum y-value.”)
What is the absolute minimum in the graph?
Where is the absolute minimum located?
What do you notice about the locations of absolute extrema? Where could they occur?
Monday, March 18, 2019
MAT 145

4. Absolute and Relative Extremes
Absolute (Global) Extreme: An output of a function such that it is either the greatest (maximum) or the least (minimum) of all possible outputs.
Relative (Local) Extreme: An output of a function such that it is either the greatest (maximum) or the least (minimum) in some small neighborhood along the x-axis.
Extreme Value Theorem: For f(x) continuous on a closed interval, there must be extreme values. If f is continuous on a closed interval [a,b] then f attains an absolute maximum value f(c) and an absolute minimum value f(d) at some numbers c and d in [a,b].
Fermat’s Theorem: If f has a local max or min at x = c and if f ’(c) exists then f ’(c) = 0.
Critical Point: An interior point (not an endpoint) on f(x) with f ’(x) = 0 or f ’(x) undefined. Note: The function MUST EXIST at x = c for a critical point to exist at x = c.
Monday, March 18, 2019
MAT 145

5. Absolute and Relative Extremes
Ways to Find Extrema
Local Extremes: examine behavior at critical points
Absolute Extremes: examine behavior at critical points and at endpoints
Example
Determine critical numbers, absolute extrema, and relative extrema for the unrestricted function (all possible domain values) and then for the restricted domain [−1,3].
Monday, March 18, 2019
MAT 145

6. Extreme Value Theorem: If f is continuous on the closed interval [a,b] then f attains an absolute maximum value f(c) and an absolute minimum value f(d) at some numbers c and d in [a,b].
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7. Absolute Extrema—Closed Interval Method
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8. Absolute (global) Extremes and Relative (local) Extremes
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9. Relative (Local) Extrema
In the graph, Relative (Local) Maxima are:
f(b) (y-value) found at x=b
f(d) (y-value) found at x=d
These values are greater than all the
other y-values in a small neighborhood
immediately to the right and left.
The Relative (Local) Minima are:
f(c) (y-value) found at x=c
f(e) (y-value) found at x=e
These values are less than all the other y-values nearby.
Monday, March 18, 2019
MAT 145

10. Relative (Local) Extrema
Where could relative extrema occur?
Critical numbers are the locations where local extrema could occur. Critical points are the points (x- and y-values) that describe both the locations and function values at those points.
Determine critical numbers for
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11. Fermat’s Theorem
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12. Absolute Extrema Where and what are the absolute and local extrema?
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13. Absolute Extrema Where and what are the absolute and local extrema?
Monday, March 18, 2019
MAT 145

14. Absolute and Relative Extremes
Ways to Find Extrema
Local Extremes: examine behavior at critical points
Absolute Extremes: examine behavior at critical points and at endpoints
Example
Determine critical numbers, absolute extrema, and relative extrema for the unrestricted function (all possible domain values) and then for the restricted domain [−1,3].
Monday, March 18, 2019
MAT 145

15. What does f’ tell us about f?
If f’(c)= 0, there is a horizontal tangent to the curve at x=c. This may mean there is a local max or min at x=c.
If f’(c) is undefined, there could be a discontinuity, a vertical tangent, or a cusp (sharp point) at x=c. If f(x) is continuous at x=c, there may be a local max or min at x=c.
Monday, March 18, 2019
MAT 145

16. Absolute and Relative Maximums and Minimums
Use the graph of f ’(x) to describe a strategy for identifying the global and local extrema of f, knowing f ’(x). m a t h
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17. First derivative test
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18. Absolute and Relative Maximums and Minimums
Must every continuous function have critical points on a closed interval? Explain.
Can an increasing function have a local max? Explain.
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19. Concavity of a Function
Concavity Animations
More Concavity Animations
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20. Concavity of a Function
Concavity Animations
More Concavity Animations
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21. What does f’’ tell us about f?
If f’’(c)> 0, then the original curve f(x) is concave up at x=c.
If f’’(c)< 0, then the original curve f(x) is concave down at x=c.
If f’’(c)= 0, then f(x) is neither concave up nor concave down at x=c. And there could be an inflection point on f(x) at x=c.
If f’’(c) is undefined, there could be a discontinuity, a vertical tangent, or a cusp (sharp point) in f’(x) at x=c. There may be a change of concavity in f(x) at x=c.
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22. Inflection Point
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23. First Derivative Test, Concavity, Second Derivative Test (Sec. 4.3)
Determining Increasing or Decreasing Nature of a Function
If f’(x) > 0, then f is _?_.
If f’(x) < 0, then f is _?_.
Using the First Derivative to Determine Whether an Extreme Value Exists: The First Derivative Test (and first derivative sign charts)
If f’ changes from positive to negative at x=c, then f has a _?_ _?_ at c.
If f’ changes from negative to positive at x=c, then f has a _?_ _?_ at c.
If f’ does not change sign at x=c, then f has neither a local max or min at c.
Concavity of f
If f’’(x) > 0 for all x in some interval I, then the graph is concave up on I.
If f’’(x) < 0 for all x in some interval I, then the graph is concave down on I.
Second derivative Test
If f’(c) = 0 and f’’(c) > 0, then f has a local min at c.
If f’(c) = 0 and f’’(c) < 0, then f has a local max at c.
Monday, March 18, 2019
MAT 145

24. Info about f from f ’
Here’s a graph of g’(x). Determine all intervals over which g is increasing and over which g is decreasing. Identify and justify where all local extremes occur.
Monday, March 18, 2019
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25. Info about f from f ’’
Here’s a graph of h”(x). Determine all intervals over which h is concave up and over which h is concave down. Identify and justify where all points of inflection occur.
Monday, March 18, 2019
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26. Pulling it all together
For f(x) shown below, use calculus to determine and justify:
All x-axis intervals for which f is increasing
All x-axis intervals for which f is decreasing
The location and value of every local & absolute extreme
All x-axis intervals for which f is concave up
All x-axis intervals for which f is concave down
The location of every point of inflection.
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27. Monday, March 18, 2019
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28. Identify Extrema From a Graph
Graph each function. Identify all global and local extremes. For each of those, write a sentence based on this template:
At x = ?, there is a (local/global) (max/min) of y = ?
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29. Identify Extrema From a Graph
At x = 1 there is a global max of 5. At x = 4 there is a global min of 3.
At x = 0 there is a global max of 4.
There is no global min.
At x = -1 there is a global min of 1/e.
There is no global max.
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30. Determine the Critical Numbers
For each function, determine every critical number. Unless otherwise restricted, assume that each function’s domain includes all possible values for which that function is defined.
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31. Determine the Critical Numbers
For each function, determine every critical number. Unless otherwise restricted, assume that each function’s domain includes all possible values for which that function is defined.
Monday, March 18, 2019
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32. Identify Extrema Using Critical Numbers
For each function, determine every critical number, and then use those critical numbers to determine all absolute extreme values. Note the domain restrictions.
For each extreme value, write a sentence based on this template:
At x = _?_, there is an absolute (max/min) of _?_.
Monday, March 18, 2019
MAT 145

33. Identify Extrema Using Critical Numbers
At x = √8 there is a global max of 8. At x = −1 there is a global min of −√15.
At x = −2 there is a global max of 92.
At x = 3 there is a global min of −158.
At x = 1 there is a global max of 1.
At x = 0 there is a global min of 0.
Monday, March 18, 2019
MAT 145

34. Absolute and Relative Extremes
Ways to Find Extrema
Local Extremes: Examine behavior at critical points.
Absolute Extremes: Examine behavior at critical points and at endpoints.
Example
Determine critical numbers, absolute extrema, and relative extrema for the unrestricted function (all possible domain values) and then for the restricted domain [−3,1].
Monday, March 18, 2019
MAT 145