AP Calculus AB: 8.4.2 Cusp Points and the Derivative
This content explains how functions with fractional exponents can have cusp points—sharp turns where the derivative is undefined. It guides through analyzing critical points, concavity, and inflection points using first and second derivatives to identify cusp behavior on graphs.
Cusp Points and the Derivative
Functions with fractional exponents could potentially have cusp points. A cusp point is a point where the curve abruptly
changes direction.
• To graph a function:
1. Find critical points using the first derivative.
2. Determine where the function is increasing or decreasing.
3. Find inflection points using the second derivative.
4. Determine where the function is concave up or concave down.
Key Terms
Cusp Points and the Derivative
Functions with fractional exponents could potentially have cusp points. A cusp point is a point where the curve abruptly
changes direction.
•...
note
Expect to see strange behavior in the graphs of functions with fractional exponents.
First, find critical points by setting ...
Which of the following graphs describes a function with these characteristics?
f ′(x) < 0 when x < 1.
f ′(1) is undefined. f ′(x) > 0 when x > 1.
f ″(x) < 0 when x ≠ 1.
This graph has negative slope when x < 1, positive slope when x > 1, an undefined slope at x = 1, and is concave down everywhere but x = 1. I...
A cusp point (or a point where the curve changes direction abruptly instead of smoothly) can occur when:
The first derivative is undefined
True or false?
The graph of y = 3x^ 5/3 − x ^2/3 has a cusp at x = 0.
true
Which of the following statements about the curve y = 1/3 (x 2−1)^2/3 is true?
The curve has a cusp at x = 1
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| Term | Definition |
|---|---|
Cusp Points and the Derivative | Functions with fractional exponents could potentially have cusp points. A cusp point is a point where the curve abruptly |
note |
|
Which of the following graphs describes a function with these characteristics? | This graph has negative slope when x < 1, positive slope when x > 1, an undefined slope at x = 1, and is concave down everywhere but x = 1. It fits the description of f (x). |
A cusp point (or a point where the curve changes direction abruptly instead of smoothly) can occur when: | The first derivative is undefined |
True or false? The graph of y = 3x^ 5/3 − x ^2/3 has a cusp at x = 0. | true |
Which of the following statements about the curve y = 1/3 (x 2−1)^2/3 is true? | The curve has a cusp at x = 1 |
Which of the following is the graph of y=∣x^3−3x−2∣? | The graph of y=∣x3−3x−2∣y = |x^3 - 3x - 2|y=∣x3−3x−2∣ is the graph of y=x3−3x−2y = x^3 - 3x - 2y=x3−3x−2 reflected above the x-axis wherever x3−3x−2x^3 - 3x - 2x3−3x−2 is negative. |
Which of the following is the graph of the equation f(x)=x^5/3−4x^2/3? | The graph has a cusp at x=0x=0x=0 and local extrema near x=1x=1x=1 and x=4x=4x=4. It is neither symmetric nor smooth at zero. |