284 PROPERTIES OF THE INTEGERS [CHAP. 1111.5. Prove Proposition 11.3: Supposea≤b, andcis any integer. Then: (i)a+c≤b+c,
(ii)ac=bcwhenc>0; butac=bcwhenc<0.
The proposition is certainly true whena=b. Hence we need only consider the case whena<b, that is, when
b−ais positive.(i) The following difference is positive:(b+c)−(a+c)=b−a. Hencea+c<b+c.
(ii) Suppose c is positive. By property [P 1 ] of the positive integersN, the productc(b−a) is also positive. Thus
ac < bc.Now supposecis negative. Then−cis positive, and the product(−c)(b−a)=ac−bcis also positive. Accordingly,
bc < ac, whenceac > bc.11.6. Prove Proposition 11.4 (iii):|ab|=|a||b|.
The proof consists of analysing the following five cases: (a)a=0orb=0; (b)a>0 andb>0; (c)a>0 and
b<0; (d)ba <0 andb>0; (e)ba <0 andb<0. We only prove the third case here. (c) Sincea>0 andb<0,
|a|=aand|b|=−b. Alsoab <0. Hence|ab|=−(ab)=a(−b)=|a||b|.11.7 Prove Proposition 11.4 (iv):|a±b|≤|a|+|b|.
Nowab≤|ab|=|a||b|, and so 2ab≤ 2 |a||b|. Hence
(a+b)^2 =a^2 + 2 ab+b^2 ≤|a|^2 + 2 |a||b|+|b|^2 =(|a|+|b|)^2But√
(a+b)^2 =|a+b|. Thus the square root of the above yields|a+b|≤|a|+|b|. Also,
|a−b|=|a+(−b)|≤|a|+|−b|=|a|+|b|MATHEMATICAL INDUCTION,WELL-ORDERING PRINCIPLE
11.8. Prove the proposition that the sum of the first n positive integers isn(n+ 1 )/2; that is:P (n): 1 + 2 +···+n=1
2n(n+ 1 )P( 1 )is true since 1=^12 ( 1 )( 1 + 1 ). AssumingP(k)is true, we addk+1 to both sides ofP(k)obtaining1 + 2 + 3 +···+k+(k+ 1 ) =
1
2
k(k+ 1 )+(k+ 1 )=
1
2
[k(k+ 1 )+ 2 (k+ 1 )]=1
2
[(k+ 1 )(k+ 2 )]This isP(k+ 1 ). Accordingly,P(k+ 1 )is true wheneverP(k)is true. By the principle of mathematical induction,
Pis true for everyn∈N.11.9. Supposea=1. ShowPis true for alln≥1 wherePis defined as follows:P (n): 1 +a+a^2 +···+an=an+^1 − 1
a− 1
P(1) is true since
1 +a=
a^2 − 1
a− 1
AssumingP(k)is true, we addak+^1 to both sides ofP(k), obtaining1 +a+a^2 +...+ak+ak+^1 =
ak+^1 − 1
a− 1+ak+^1 =
ak+^1 − 1 +(a− 1 )ak+^1
a− 1=ak+^2 − 1
a− 1
This isP(k+ 1 ). Thus,P(k+ 1 )is true wheneverP(k)is true. By the principle of mathematical induction,Pis true
for everyn∈N.