Calculus Methods

30 Intervals and Radii of Convergence

 Back to Dr. Nandor's Calculus Methods Page

 Back to Dr. Nandor's Calculus Page

Back to Dr. Nandor's Math Pages

Back to Wellington

 

                After looking at which series converge and which don't, it is

                finally time to use them. When series are not simply series of

                constants, but also of variables, life gets interesting.

 

 

        1) Identify the value about which the series is centered (the in

        your power series, when phrased in the form .

 

 

        2) Find the Radius of Convergence (see lesson 55).

 

                2A) You will usually use the Root Test (see lesson 53), since

                you are dealing with powers of x.

 

                2B) Don't forget to put your Root Test (or Ratio Test) answer

                into the form . is your Radius.

 

 

        3) The Interval of Convergence will be from to , but you

        need to check those endpoints.

 

        4) Check the endpoints by plugging in the values and

        into the function. If the series converges at that point,

        include the endpoint; if not, then do not include the endpoint.

 

 

 

        Example #1: Find the Interval of Convergence of .

 

        1) We are centered about .

 

 

        2) Using the Root Test, we find , so .

 

        

        3) Our interval then, will be from 1 to 3.

 

 

        4)    , which is an alternating series that does

                    not converge (fails the nth term test).

               , which also diverges due to the nth term

                    test.

                So we do not include either endpoint, and our Interval of

                Convergence is .

 

 

 

 

 

        Example #2: Find the Interval of convergence of .

 

        1) We are centered about .

 

 

        2)

 

                The "problem" here is that the left side NEVER converges. It

                always approaches infinity. Thus, there are no values for

                which this function converges and .

 

        3) There is no Radius of Convergence, so there are no endpoints.

 

        4) No Interval of Convergence.

 

 

 

                 

        Example #3: Find the Interval of Convergence of the function

        .

 

        1) We are centered about

 

        2)

 

                Here we have an example where the series ALWAYS

                converges, so the Radius is infinite.

 

 

        3) There are no endpoints since the radius is infinite.

 

 

        4) The Interval of Convergence is .

 

 

 

 

        Example #4: Find the Interval of Convergence of the function

        .

 

        1) We are centered about .

 

        2)

                  Our Radius is

 

        3) Our endpoints are -12 and -2.

 

        

        4)    , which is the Alternating

                    Harmonic Series, which converges.

 

                , which is the Harmonic Series,

                    which diverges.

 

        Our interval of convergence is thus .

 

On to Method 31 - Generating Geometric Power Series

 Back to Dr. Nandor's Calculus Methods Page

 Back to Dr. Nandor's Calculus Page

Back to Dr. Nandor's Math Pages

Back to Wellington