1.6 The Completeness Property 43Definition 1.6.14 (-oo and +oo as infimum and supremum): Let JR denote
the complete ordered field,(a) If a set A s;;; JR has no lower bound, we say that inf A= -oo;
(b) If a set A s;;; JR has no upper bound, we say that sup A = +oo;
~(c) Since every real number is a lower bound of 0, the empty set has ...----no
greatest lower bound, so we defiEe inf 0 = +oo ..
(d) Since every real number is an upper bound of 0, the empty set has no
least upper bound, so we define sup 0 = -oo.It is important to remember that -oo and +oo are not real numbers, but are
merely symbols used to conveniently convey certain carefully defined situations
(here, to denote that a set is unbounded below or above). In addition, we adopt
the universal convention that all real numbers x obey the inequalities-oo < x < +oo.
In analysis, the symbols -oo and +oo are frequently used in inequalities
and equations, whenever it is convenient. But these symbols are always used
with the understanding that they do not represent real numbers.EXERCISE SET 1.6-BIn Exercises 1- 5 below, assume that A, B s;;; F, a complete ordered field.l. Prove Theorem 1.6.12. (See Exercise 1.6-A.12.)
- Suppose A s;;; B and A -j. 0. Prove that
(a) if Bis bounded below, then so is A , and inf A;:::: inf B.
(b) if B is bounded above, then so is A, and sup A ::::; sup B.- Suppose A is a nonempty set of F that is bounded above in F , and let
B be the set of all upper bounds of A. Prove that B has a minimum
element, and sup A = min B. - Suppose A is a nonempty set of F that is bounded below in F, and let B
be the set of all lower bounds of A. Prove that B has a maximum element,
and sup A= maxB. - Suppose A and Bare nonempty subsets of F bounded above in F. Prove
that AU Bis bounded above, and sup( AU B) =max{ sup A, sup B}. - Modify the proof of Theorem 1.6.10 to prove that if a> 0 in a complete
ordered field F, then :3 x E F 3 x^2 = a.