6.9. Prove that 1.3+2 6.10. Let r #1 be a real number. Use induction to prove that a + ar + ar? + ...+ ar- = for every positive integer n. Prove that I+ for every positive integer n.

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SECTION 6.1 EXERCISES 6.1. Which of the sets are well-ordered? | 10 GAGLA (b) S={-2, – 1, 0, 1, 2} mobans nob sr p is a prime} = {2, 3, 5, 7, 11, 13, 17, . }. || well-ordered. 2 Prove that every nonempty set of negative integers has a largest element. .. %3D (1) by mathematical induction and s (2) by adding 1 + 3 + 5 + · . ·+ (2n – 1) and (2n – 1) + (2n – 3) + · ·· +1. | | 65. Use mathematical induction to prove that <1+5+9+...+ (4n – 3) = 2n2 –n for every positive integer n. 66 (a) We have seen that 12 + 2² + ·. .+n² is the number of squares in an n × n square composed of n² 1 × 1 squares. What does 13 + 2³ + 3³ +. +n³ repreșent geometrically? 12 fn an (b) Use máthematical induction to prove that 13 + 23 + 33+...+n = n²(n + 1)² for every positive Lorborsk integer n. 4. I 12 CO 6.7. Find another formula suggested by Exercises 6.4 and 6.5 and verify your formula by mathematical induction. 6.8. Find a formula for 1+4 +7+• +(3n – 2) for positive integers n and then verify your formula by mathematical induction. 6.9. Prove that 1.3+2.4+3.5+ . ..+n(n+ 2) = "(n+1)(2n+7) for every positive integer n. 9. = a= for every 6.10. Let r + be a real number. Use induction to prove that a + ar + ar²+.+ ar"-1 positive integer n. ... 6.11. Prove that +as +…+ 1. (n+2)(n+3) GEGL for every positive integer n. 6.12, Consider the open sentence P(n): 9 + 13 +. . + (4n + 5) = 4n²+14n+1 w where n e N. ... %3D 2. ule (a) Verify the implication P(k) = P(k + 1) for an arbitrary positive integer k. (b) Is Vn e N, P(n) true? llupitedmy 8.0 moos