716 Appendix I
The first basic theorem shows us that there can be at most one number L
for which lim f (x) = L.Theorem A
(2) If lim f(x) = L1, lim f(x) = L2 then L2 = L1.
x- a x-aLet e be a given positive number. Then e/2 is also a positive number
which we could call el. The first hypothesis of the theorem implies that
there is a positive constant S1, such that(3) if(x) - L11 <whenever x 0 a and Ix - at < S1. The second hypothesis implies that
there is a positive number S2 such that(4) If(x) - L21 <whenever x 0 a and Ix - al < S2. Let S be the lesser of Si and S.
Then, when x 34 a and Ix - al < 5, the two inequalities (3) and (4)
both hold and hence(5) IL2 - L11 = I [f(x) - L1 - [f(x) - L2}I
f(x)-Lll+lf(x)-L21 <2+2=e.If we suppose that IL2 - L11 0 0, then we could let e be the positive
number JIL2 - L1I and reach the false conclusions that IL2 - LI1 <
J1L2 - L11 and 1 < - and 2 < 1. Therefore, IL2 - L11 = 0 and hence
L2 = L1. This proves Theorem A. The last part of the proof involves
a principle that is very often used. If h is a number and if Ihj < e when-
ever e > 0, then It = 0.Theorem B
If b isa constant, then(6) limb = b.
x- aThis theorem tells us that if,f(x) = b, where b is a constant, then(7) lim f (x) = b.
x-aTo prove the result, let e > 0. Since f(x) - b = 0 for each x, we can
let 3 = e and conclude that I f(x) - bI < e when x 0 a and Ix - at < S.