Download
1 / 34
360 likes | 536 Views
MAT 1234 Calculus I. Section 3.3 How Derivatives Affect the Shape of a Graph (II). http://myhome.spu.edu/lauw. Next. Wednesday Quiz: 3.3,3.4 Exam II: Next Thursday. Preview. We know the critical numbers give the potential local max/min. How to determine which one is local max/min?.
E N D
MAT 1234Calculus I Section 3.3 How Derivatives Affect the Shape of a Graph (II) http://myhome.spu.edu/lauw
Next • Wednesday Quiz: 3.3,3.4 • Exam II: Next Thursday
Preview • We know the critical numbers give the potential local max/min. • How to determine which one is local max/min?
Preview • We know the critical numbers give the potential local max/min. • How to determine which one is local max/min? • 30 second summary!
Preview • We know the critical numbers give the potential local max/min. • How to determine which one is local max/min? • 30 second summary! • We are going to develop the theory carefully so that it works for all the functions that we are interested in.
Preview Part I • Increasing/Decreasing Test • The First Derivative Test Part II • Concavity Test • The Second Derivative Test
Definition (a) A function f is called concave upward on an interval I if the graph of f lies above all of its tangents on I. (b) A function f is calledconcave downward on an interval I if the graph of f lies below all of its tangents on I.
Concavity f is concave up on I • Potential local min.
Concavity f is concave down on I • Potential local max.
Concavity Concave down Concave up c f has no local max. or min. f has an inflection point at x=c
Definition • An inflection point is a point where the concavity changes (from up to down or from down to up)
Concavity Test (a) If on an interval I, then f is concave upward on I. (b) If on an interval I, then f is concave downward on I.
Concavity Test (a) If on an interval I, then f is concave upward on I. (b) If on an interval I, then f is concave downward on I. Why?
Why? implies is increasing. i.e. the slope of tangent lines is increasing.
Why? implies is decreasing. i.e. the slope of tangent lines is decreasing.
Example 3 Find the intervals of concavity and the inflection points
Example 3 (a) Find , and the values of such that
Example 3 (b) Sketch a diagram of the subintervals formed by the values found in part (a). Make sure you label the subintervals.
Example 3 (c) Find the intervals of concavity and inflection point(s). f( )= f has an inflection point at ( , )
Expectation • Answer in full sentence • The inflection point should be given by the notation
The Second Derivative Test Suppose is continuous near c. (a) If and , then f has a local minimum at c. (b) If and , then f has a local maximum at c. (c) If , then no conclusion (use 1st derivative test)
Second Derivative Test Suppose If then f has a local min. at x=c f”(c)>0 f’(c)=0 c
Second Derivative Test Suppose If then f has a local max. at x=c f”(c)<0 f’(c)=0 c
Example 4 (Example 2 Revisit) Use the second derivative test to find the local max. and local min.
Example 4 (Example 2 Revisit) (a) Find the critical numbers of
Example 4 (Example 2 Revisit) (b) Use the Second Derivative Test to find the local max/min of • The local max. value of f is • The local min. value of f is
The Second Derivative Test (c) If f’’(c)=0, then no conclusion
The Second Derivative Test (c) If f’’(c)=0, then no conclusion
The Second Derivative Test (c) If f’’(c)=0, then no conclusion
The Second Derivative Test (c) If f’’(c)=0, then no conclusion
The Second Derivative Test Suppose is continuous near c. (a) If and , then f has a local minimum at c. (b) If and , then f has a local maximum at c. (c) If , then no conclusion (use 1st derivative test)
Which Test is Easier? • First Derivative Test • Second Derivative Test
Classwork • Do part (a), (d) and (e) only
