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Further Pure 1

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Further Pure 1 Lesson 11 Proof by induction – PowerPoint PPT presentation

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Title: Further Pure 1


1
Further Pure 1
  • Lesson 11
  • Proof by induction

2
Mathematical Statements
  • In this lesson we are going to look at proving
    mathematical statements.
  • For example 3n-1 is always an even number
  • The problem is though, how can we prove this to
    be true as there are infinitely many values of n
    to try?
  • We can see that if n 1, then 31-1 2 Even
  • and if n 2, then 32-1 8 Even
  • and if n 3, then 33-1 26 Even
  • But it is impossible to test every single value
    of n to see if the statement is true.
  • We are going to now look at the idea of proof by
    induction.

3
Proof by induction
  • Here is an example to think about.
  • An old woman is asked how old she is, and replies
    I am 100 years old. No record has been kept of
    her birthday so how do we now she is 100?
  • Answer Because she was 99 last year.
  • With proof by induction we assume that a
    statement is true and then try to prove that the
    next result will also be true.
  • If this principle holds then as long as the first
    value works then automatically so must the
    second, then the third and so on and so on.
  • Its a bit like pushing over a domino line.

4
Proof by induction
  • Now we can go back to our original problem from
    the first slide.
  • Prove that 3n-1 is always an even number
  • Lets assume that 3k-1 is always even, for n k.
  • Now 3k1-1 33k-1
  • 33k-3 2
  • 3(3k-1) 2
  • 3(Even) Even
  • Even
  • So we have shown that if 3n-1 is even for n k
    then 3n-1 will be even for n k1.
  • Now if k 1, 3k-1 Even
  • The domino effect kicks in and it must be true
    for n 2,3,8

5
Questions
  • 1) Prove that, for all positive integers n,
  • 1 2 3 n (n/2)(n1)
  • 2) Prove that, for all positive integers n,
  • 12 22 32 n2 (n/6)(n1)(2n1)
  • 3) Prove that, for all positive integers n,
  • 13 23 33 n3 (n2/4) (n1)2
  • These are important results and we shall learn
    some more about them in lesson 12

6
Solution 1
  • Prove that, for all positive integers n,
  • 1 2 3 n (n/2)(n1)
  • First we start by assuming that it is true for n
    k and try to show that it will be true for n
    k1
  • This shows that if n k works then n k1 will
    also work.
  • So if n 1, then the sum of 1 is 1 0.512 1
    which is the sum of 1.
  • Therefore by induction the original statement is
    true for all n.

7
Solution 2
  • Prove that, for all positive integers n,
  • 12 22 32 n2 (n/6)(n1)(2n1)
  • First we start by assuming that it is true for n
    k and try to show that it will be true for n
    k1
  • This shows that if n k works then n k1 will
    also work.
  • So if n 1, then the sum of 1 is 1
    (1/6)123 1 which is the sum of 1.
  • Therefore by induction the original statement is
    true for all n

8
Solution 3
  • Prove that, for all positive integers n,
    13 23 33 n3 (n/4)2(n1)2
  • First we start by assuming that it is true for n
    k and try to show that it will be true for n
    k1
  • This shows that if n k works then n k1 will
    also work.
  • So if n 1, then the sum of 1 is 1 0.254 1
    which is the sum of 1.
  • Therefore by induction the original statement is
    true for all n

9
More Proofs by induction 1
  • A sequence is defined by un1 4un 3, u1 2
  • Prove that un 4n-1 1
  • We start by assuming that n k will work and
    investigate what happens with n k1
  • uk1 4uk 3
  • 4(4k-1 1) 3
  • 44k-1 4 3
  • 4k 4 3
  • 4k 1

10
More Proofs by induction 2
  • Prove that un 4n 6n 1 is divisible by 9 for
    all n gt 0.
  • uk1 4k1 6(k1) 1
  • 4k1 6k 6 1
  • 4k1 6k 5
  • 44k 24k 18k 4 4 5
  • With this line I have just added in values so
    that I can factorise to make un
  • (44k 24k 4) 18k 4 5
  • 4(4k 6k -1) 18k 9
  • 4(uk) 9(2k 1)
  • This proves that uk1 is divisible by 9 because
    uk is divisible by 9 and the second part 9(2k
    1) must also be divisible by 9.
  • Now if n 1, then u1 41 61 1 9 which is
    divisible by 9.
  • This proves that un must always be divisible by 9
    for all n gt 0.

11
Enrichment problem
  • Let P(n) be the statement that
  • is divisible by 44.
  • I shall show this is true if n is any positive
    integer!
  • If n1 then is equal
    to 44
  • so is divisible by 44!
  • So the statement is clearly true when n1.

12
Assume statement is true for nk
  • We suppose that the statement is true for nk
    where k is some positive integer.
  • So we assume that
    is divisible by 44.
  • We want to then show that the statement must also
    be true for nk1.

13
Considering nk1
  • We therefore want to consider
  • (this is with nk1).
  • We want to show this is divisible by 44.
  • All we are allowed to assume is that
  • Is divisible by 44 (the case nk).
  • So lets see if we can express
    in terms of .

14
The trick!
  • So if is divisible by 44
    with nk then it is also divisible by 44 with
    nk1.

15
The conclusion
  • So we have shown that is
    divisible by 44 with n1.
  • If it is divisible by 44 with nk, for any
    positive integer k, then it follows that it is
    divisible by 44 with nk1.
  • Therefore it follows that
    must be divisible by 44 for all positive
    integers n!
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