How do you find #f^7(0)# where #f(x)=x^2ln(1+x)#?

2 Answers
Mar 14, 2017

#f^((7))(0)=1008#

Explanation:

We can construct the Maclaurin sequence for #f(x)=x^2ln(1+x)#. Start with:

#1/(1-x)=sum_(n=0)^oox^n#

Replace #x# with #-x#:

#1/(1+x)=sum_(n=0)^oo(-x)^n=sum_(n=0)^oo(-1)^nx^n#

Integrate:

#intdx/(1+x)=sum_(n=0)^oo(-1)^nintx^ndx#

#ln(1+x)=C+sum_(n=0)^oo(-1)^nx^(n+1)/(n+1)#

At #x=0# we see that #C=0#:

#ln(1+x)=sum_(n=0)^oo(-1)^n/(n+1)x^(n+1)#

Multiply by #x^2#:

#x^2ln(1+x)=x^2sum_(n=0)^oo(-1)^n/(n+1)x^(n+1)=sum_(n=0)^oo(-1)^n/(n+1)x^(n+3)#

We now have the Maclaurin series for #f(x)=x^2ln(1+x)#.

The terms of a any general Maclaurin series are given by:

#f(x)=sum_(n=0)^oof^((n))(0)/(n!)x^n#

So the #x^7# term of a general Maclaurin series is #f^((7))(0)/(7!)x^7#.

Using the Maclaurin series for #x^2ln(1+x)#, we see that the #x^7# term will occur when #n=4#, which gives a term of #(-1)^4/(4+1)x^(4+3)=1/5x^7#.

So the two coefficients of the #x^7# terms must be equal:

#1/5=f^((7))(0)/(7!)#

#f^((7))(0)=(7!)/5=1008#

Mar 14, 2017

We know that the power series for a function is unique. It does not matter how we obtain the power series (it could from the Binomial Theorem, a Taylor Series, or a Maclaurin series).

As we are looking for #f^((7))(0)# let us consider the Taylor Series for #f(x)# about #x=0#, ie its Maclaurin series.

By definition:

# f(x) = f(0) + f'(0)x + (f''(0))/(2!)x^2 + (f^((3))(0))/(3!)x^3 + ... + (f^((n))(0))/(n!)x^n + ... #

The (well known) Maclaurin Series for #ln(1+x)# is given by:

# ln(1+x) = x-x^2/2+x^3/3-x^4/4+x^5/5 ... #

And so it must be that the Maclaurin Series for #x^2ln(1+x)# is given by:

# x^2ln(1+x) = x^2(x-x^2/2+x^3/3-x^4/4+x^5/5 +... )#
# " " = x^3-x^4/2+x^5/3-x^6/4+x^7/5+ ... #

And if we equate the coefficients of #x^7# from this derived series and the definition then we have:

# \ \ \ (f^((7))(0))/(7!)= 1/5 #

# :. f^((7))(0) = (7!)/(5) #
# " " = 5040/5 #
# " " = 1008 #