296 CHAPTER 5 Series and Differential Equations
- Consider the function defined by settingf(x) = ln(1 + sinx).
(a) Determine the Maclaurin series expansion for f(x) through
thex^4 term.
(b) Using (a) determine the Maclaurin series expansion for the
functiong(x) = ln(1−sinx).
(c) Using (a) and (b), determine the Maclaurin series expansion
for ln secx.
- Consider the following integral
I =
∫ 1
0
(∫ 1
0
dy
1 −xy
)
dx.
(a) Using integration by parts, show that the internal integral is
equal to
−ln(1−x)
x
.
(b) Determine the Maclaurin series expansion for this.
(c) Use a term-by-term integration to show that
I =
∑∞
n=1
1
n^2
,
(which, as mentioned on page 276 is =π
2
6 .See the footnote.
(^20) )
- Here’s a self-contained proof that
∑∞
n=1
=
π^2
6
.(See the footnote.^21 )
Step 1. To show that for any positive integerm,
∑m
k=1
cot^2
kπ
2 m+ 1
=
m(2m−1)
3
.
To complete step 1, carry out the following arguments.
(^20) Using the variable changeu=^12 (y+x), v=^12 (y−x), one can show in the above “double
integral” is equal toπ 62 , giving an alternative proof to that alluded in HH, Exercise 15, page 228.
Showing that the double integral has the correct value requires some work!
(^21) This is distilled from I. Papadimitriou,A Simple Proof of the Formula ∑∞
k=1
k^12 = π 62 .Amer.
Math. Monthly 80 , 424–425, 1973.