Advanced High-School Mathematics

(Tina Meador) #1

300 CHAPTER 5 Series and Differential Equations


u=f(n)(t) dv=

(x−t)(n−1)
(n−1)!
dt.

du=f(n+1)(t)dt v=−
(x−t)n
n!

From the above, one obtains


∫x


a

f(n)(t)
(n−1)!

(x−t)(n−1)dt = −f(n)(t)

(x−t)n
n!

∣∣
∣∣

x
a

+

∫x
a

f(n+1)(t)
n!

(x−t)ndt

=

f(n)(a)
n!

(x−a)n+

∫x
a

f(n+1)(t)
n!

(x−t)ndt

Plugging this into the induction hypothesis shows that the original
statement is correct for alln.
Next, note that if F =F(t) is a continuous function oft, then one
has that ∫b


a F(t)dt=F(c)(b−a)
for some numbercbetweenaandb. (IndeedF(c) is the average value
ofF on the interval [a,b].) Using the substitutionu= (x−t)(n+1), and
applying the above observation, we have


(n+ 1)

∫x
a F(t)(x−t)

ndt =
∫(x−a)(n+1)
0 F(x−

n+1√u)du

= F(x− n+1


α)(x−a)n+1,

whereαis between 0 and (x−a)(n+1).If we setc=x− n+1



α we see
thatcis betweenaandxand that


(n+ 1)

∫x
a F(t)(x−t)

ndt=F(c)(x−a)(n+1).

Now setF(t) =

f(n+1)(t)
n!

and apply the above to infer that
∫x
a

f(n+1)(t)
n!
(x−t)ndt=

f(n+1)(c)
(n+ 1)!
(x−a)n+1.

This completes the proof.

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