Calculus Methods

31 Generating Geometric Power Series

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                The key to converting certain types of functions into power

                series is to use the definition of a Geometric Power Series:

                                                   

 

        1) If the denominator can be factored, use the method of

        separating partial fractions (see method 03) to split the single

        fraction into multiple fractions.

 

 

        2) You will either be told about what value the series should be

        found, or you can decide for yourself. In either case, you will have .

 

 

        3) For each fraction, you will have either a denominator that looks

        like . If you have some more complicated factors than this,

        revert to using the Taylor Series (see method 32) form of the

        expansion.

 

 

        4) You must arrange for the denominator to look like

        where. This will either take adding a zero, or completing the

        square and THEN adding a zero. If you subtract from the , you

        should note that you must also add to the entire denominator to

        cancel it out. Your new denominator is thus . If we

        then factor out , our denominator has the form

        . This may look complicated with variables, but

        when we deal with numbers, it's typically not so bad.

 

        

        5) The factor of outside is simply a coefficient. The

        is what we will call .

 

        6) Use the formula to write your power series.

 

        7) Don't forget that a power series is never fully dressed without a

        smile (and an Interval of Convergence (see method 30)). The nice

        part about geometric series, is that they always diverge at their

        endpoints, so we don't have to test them.

 

 

 

        Example: Find the power series for the function

        centered about .

 

 

        1) The denominator is already factored.

 

        2)

 

        3) We already have a denominator in the correct form, .

 

        4) We need to add 3 just to the . Our new function looks like:

        . You can see that we have

        essentially "done" nothing, since we have subtracted 6 and added 6.

        Continuing, .

        Finally, we need to make sure that we are subtracting on the

        bottom.

        

 

 

        5) So now we see that .

 

 

        6)

 

                It is customary, however, to keep any separate, and to

                keep separate as well. Our answer, then, is

                or . Either form is

                common.

 

        7) Using method 30, we find that the Interval of Convergence is .

 

        The final answer is thus , .

 

 

 

 

On to Method 32 - Generating Taylor Series and Taylor Polynomials

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