1 / 6

Strong Mathematical Induction

Strong Mathematical Induction. Principle of Strong Mathematical Induction. Let P(n) be a predicate defined for integers n; a and b be fixed integers with a ≤b . Suppose the following statements are true: 1. P(a), P(a+1), … , P(b) are all true (basis step) 2. For any integer k>b,

naomi
Download Presentation

Strong Mathematical Induction

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript


  1. Strong Mathematical Induction

  2. Principle of Strong Mathematical Induction • Let P(n) be a predicate defined for integers n; a and b be fixed integers with a≤b. • Suppose the following statements are true: 1. P(a), P(a+1), … , P(b) are all true (basis step) 2. For any integer k>b, if P(i) is true for all integers i with a≤i<k, then P(k) is true. (inductive step) • Then P(n) is true for all integers n≥a.

  3. Example: Divisibility by a Prime • Theorem: For any integer n≥2, n is divisible by a prime. P(n) • Proof (by strong mathematical induction): 1) Basis step: The statement is truefor n=2 P(2) because2 | 2and2 is a prime number. 2) Inductive step: Assume the statement is true for all i with 2≤i<k P(i) (inductive hypothesis) ; show that it is true for k . P(k)

  4. Example: Divisibility by a Prime • Proof (cont.): We have that for all iZ with 2≤i<k, P(i) i is divisible by a prime number. (1) We must show: P(k) k is also divisible by a prime. (2) Consider 2 cases: a) k is prime. Then k is divisible by itself. b) k is composite. Then k=a·b where2≤a<k and 2≤b<k. Based on (1),p|a for some prime p. p|a and a|k imply that p|k(by transitivity). Thus, P(n) is true by strong induction. ■

  5. Proving a Property of a Sequence • Proposition: Suppose a0, a1, a2, … is defined as follows: a0=1, a1=2, a2=3, ak = ak-1+ak-2+ak-3for all integers k≥3. Then an ≤ 2n for all integers n≥0. P(n) • Proof (by strong induction): 1) Basis step: The statement is truefor n=0: a0=1≤1=20 P(0) for n=1: a1=2≤2=21 P(1) for n=2: a2=3≤4=22 P(2)

  6. Proving a Property of a Sequence • Proof (cont.): 2) Inductive step: For any k>2, Assume P(i) is true for all i with 0≤i<k: ai≤ 2i for all0≤i<k . (1) Show that P(k) is true: ak≤ 2k(2) ak= ak-1+ak-2+ak-3 ≤ 2k-1+2k-2+2k-3 (based on (1)) ≤ 20+21+…+2k-3+2k-2+2k-1 = 2k-1 (as a sum of geometric sequence) ≤ 2k Thus, P(n) is true by strong induction. ■

More Related