First & Second Derivative Test

FIRST & SECOND DERIVATIVE TEST

A. FIRST DERIVATIVE TEST

Let

1. Finding the critical points of f.

(Definition: A value is a critical point if

a. c is in the domain of the function , and

b. or does not exist)

2. Find the open interval(s) on which is increasing.

(Suppose that f is continuous at each point of , and differentiable at each point of . If for all , , then is increasing on )

3. Find the open interval(s) on which is decreasing

(Suppose that f is continuous at each point of , and differentiable at each point of . If for all , , then is decreasing on )

4. Find all relative maxima.

(Suppose f is defined on and c is a critical point, and if for x near and to the left of c, for x near and to the right of c, then is a relative maximum)

5. Find all relative minima

(Suppose f is defined on and c is a critical point, and if for x near and to the left of c, for x near and to the right of c, then is a relative minimum)

(NOTE: If the sign of is the same on both sides of c, then is not a relative extremum)

Exercise: Repeat the exercise above for

B. SECOND DERIVATIVE TEST

Let

1. Find where the graph of the function is concave up

(Suppose that f is twice-differentiable at each point of . If on , then the graph of f is concave up on )

2. Find where the graph of the function is concave down.

(Suppose that f is twice-differentiable at each point of . If on , then the graph of f is concave down on )

3. Find any points of inflection

(Definition: A point where the graph of a function has a tangent line and where the concavity changes is called a point of inflection)

(NOTE: At a point of inflection on the graph of a twice-differentiable function, . The converse is not true)

4. Use the second derivative tests to find the relative extrema.

( a. If and , then f has a relative maximum at ;

b. If and , then f has a relative minimum at )

(NOTE: The test fails if , if fails to exist, or if is hard to find)

Exercise: Repeat the exercise above for