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Proof Methods & strategies Section 1.7. Proof by Cases We use the rule of inference P 1  P 2 ...  P n  q  (P 1  q)  (P 2  q) ..  (P n  q)

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Presentation on theme: "Proof Methods & strategies Section 1.7. Proof by Cases We use the rule of inference P 1  P 2 ...  P n  q  (P 1  q)  (P 2  q) ..  (P n  q)"— Presentation transcript:

1 Proof Methods & strategies Section 1.7

2 Proof by Cases We use the rule of inference P 1  P 2 ...  P n  q  (P 1  q)  (P 2  q) ..  (P n  q)

3 Exhaustive Proof A special type of proof by cases where each case can be checked by examining an example. Good for computers.

4 Examples (n+1) 3  3 n, for n=1, 2, 3, 4 Proof: (Exhaustive) For n=1, 2 3 = 8  3 For n=2, 3 3 = 27  3 2 =9 For n=3, 4 3 = 64  3 3 =27 For n=4, 5 3 = 125  3 4 = 81

5 Examples The only consecutive positive integers < 100 that are perfect powers are 8 and 9 Proof: Perfect squares < 100 are 1, 4, 9, 16, 25, 36, 49, 64, 81 Perfect cubes < 100 are 1, 8, 27, 64 Perfect 4 th powers < 100 are 1, 16, 81 Perfect 5 th powers < 100 are 1, 32 Perfect 6 th powers < 100 are 1, 64 So all perfect powers < 100 are 1, 4, 8, 9, 16, 25, 27, 32, 36, 49, 64, 81 So the consecutive perfect powers are 8 & 9

6 Examples n 2  n for all integers. Proof: Case I: when n=0, then n 2 =0  n =0 Case II: when n  1, then n 2 =n x n  n x 1 =n Case III: when n  -1, then n 2  0  -1  n

7 Examples  x, y  R, |x y | = |x| |y| Proof: Case I: x  0 & y  0, then |x y | =x y= |x| |y| Case II: x  0 & y <0, then |x y | = - x y= x (-y)= |x| |y| Case III: x < 0 & y  0, then same as II Case IV: x < 0 & y < 0, then |x y | = x y= (-x) (-y)= |x| |y|

8 Common Error Not all cases are considered. Example: if x  R, then x 2 > 0 Case I: x> o, then.. Case II: x< 0, then.. But Case III is forgotten!

9 Uniqueness Proof Existence first, then uniqueness  ! x P(x)   x (P(x)   y ( y  x   P(y)) )

10 Example If a, b  R & a  0, then  ! r  R s.t. a r + b = 0 Proof: Clearly r=-b/a (existence) Suppose as+b =0, then ar+b=as+b, i.e. as = ab, and hence s=r because a  0.

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