5.4 Theorems about continuous and differentiable functions^32118 Prove that if x is a number, then there exist an integer N and a sequence
d1, d2, d3, of digits (a digit being one of the integers 0, 1, 2, , 9) such
that
dl d2 d
(1) N+10+102+
-10-1+1Onsx
d, d2 do-1 do + 1
< N +10 + 102+ ... + 10n-1 + 10^for each n = 1, 2, 3,. Solution: Let N = [x], so that N is the greatest
integer in x, and let 0 = x - N. Then 0 5 0 < I and the required result will
follow if we prove that there exist digits d1, d2, da, such that(2) 10 + 02 + ...
for each n = 1, 2, 3,(3)do-1 do
10-1 10,<10+2 0+
d2 10n-1 +do-1 do + 1
10,. To prove (2), it is sufficient to prove that
n
05 9-1o- 022- ... 0n<iOn-While it is of interest to take time to use (2) to determine what dl, d2, da,. ..
must be if they exist, we save time by definingintegers d,, d2, da, by the
formulas(4)
(5)(6)and, in general, for(7)Since 0 <= 0 <
over,d, = [100]d2 = [102(0 l1
OIJ
d3 =[10a(6-10 1021
each n=1,2,3,.
pn)J
1, we find that 0 5 106 < 10 and hence that d, is adigit. More-d, 5 100 < d, + l056-10<10'
so (3) holds when n = 1. Multiplying (9) by 102 gives(10) 05102(0-10)<10.