FP1 Chapter 6 - By Dr J Frost
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Transcript FP1 Chapter 6 - By Dr J Frost
FP1 Chapter 6 β Proof By
Induction
Dr J Frost ([email protected])
Last modified: 25th February 2013
What is Proof by Induction?
We tend to use proof by induction whenever we want to show some property holds
for all integers (usually positive).
Example
Show that
π
π=1 π
1
= 2 π π + 1 for all π β β.
Showing itβs true for a few values of π is not a proof.
We need to show itβs true for ALL values of π.
If itβs true for π = 1, it must be true for π = 2.
π=π
π=π
Suppose we could prove the
above is true for the first
value of π, i.e. π = 1.
π=π
If itβs true for π = 3, it must be true for π = 4.
π=π
π=π
β¦
If itβs true for π = 2, it must be true for π = 3.
And so on. Hence the statement must be true for all π.
Suppose that if we assumed itβs true
for π = π, then we could prove itβs
true for π = π + 1. Then:
Chapter Overview
We will use Proof of Induction for 4 different types of proof:
π
π=1 π
1
1
Summation Proofs
Show that
2
Divisibility Proofs
Prove that π3 β 7π + 9 is divisible by 3 for all π β β€+ .
3
Recurrence Relation
Proofs
Given that π’π+1 = 3π’π + 4,
prove that π’π = 3π β 2
Matrix Proofs
1
Prove that
0
4
= 2 π π + 1 for all π β β.
β1
3
π
1
=
0
π’1 = 1,
1 β 2π
for all π β β€+ .
π
2
Bro Tip: Recall that β€ is the set of all integers, and β€+ is the set of all
positive integers. Thus β = β€+ .
The Four Steps of Induction
For all these types the process of proof is the same:
! Proof by induction:
Step 1: Basis:
Prove the general statement is true for π = 1.
Step 2: Assumption: Assume the general statement is true for π = π.
Step 3: Inductive: Show that the general statement is then true for π = π + 1.
Step 4: Conclusion: The general statement is then true for all positive integers π.
(Step 1 is commonly known as the βbase caseβ and Step 3 as the βinductive caseβ)
Type 1: Summation Proofs
Prove the general statement is true for π = 1.
Assume the general statement is true for π = π.
Show that the general statement is then true for π = π + 1.
The general statement is then true for all positive integers π.
Step 1: Basis:
Step 2: Assumption:
Step 3: Inductive:
Step 4: Conclusion:
Show that
π
π=1(2π
β 1) = π2 for all π β β.
1 Basis Step
When π = 1, πΏπ»π = 1π=1 2π β 1 = 2 1 β 1 = 1
π
π»π = 12 = 1. πΏπ»π = π
π»π so?summation true for π = 1.
2 Assumption
Assume summation true for π = π.
?
So ππ=1(2π β 1) = π 2
3 Inductive
When π = π + 1:
π+1
π
2π β 1 =
π=1
2π β 1
π=1
= π 2 + 2π + 1
= π+1 2
Hence true when π = π + 1.
4 Conclusion
?
+ 2 π+1 β1
As result is true for π = 1, this implies true for all positive integers
?
and hence true by induction.
More on the βConclusion Stepβ
βAs result is true for π = 1, this implies true for all positive integers and hence
true by induction.β
I lifted this straight from a mark scheme, hence use this exact wording!
The mark scheme specifically says:
(For method mark)
Any 3 of these seen anywhere in the proof:
β’ βtrue for π = πβ
β’ βassume true for π = πβ
β’ βtrue for π = π + πβ
β’ βtrue for all π/positive integersβ
Test Your Understanding
Edexcel FP1 Jan 2010
?
Exercise 6A
All questions except Q2.
Type 2: Divisibility Proofs
Step 1: Basis:
Step 2: Assumption:
Step 3: Inductive:
Step 4: Conclusion:
Prove the general statement is true for π = 1.
Assume the general statement is true for π = π.
Show that the general statement is then true for π = π + 1.
The general statement is then true for all positive integers π.
Prove by induction that 32π + 11 is divisible by 4 for all positive integers π.
1 Basis Step
Let π π = 32π + 11, where π β β€+ .
π 1 = 32 + 11 = 20 which is divisible
? by 4.
2 Assumption
Assume that for π = π, π π = 32π + 11 is divisible by 4 for π β β€+ .
3 Inductive
?
π π + 1 = 32 π+1 + 11
Bro Tip: Putting in terms of 32π allows us to
better compare with the assumption case
= 32π β
32 + 11
since the power is now the same.
= 9 32π + 11
β΄ π π + 1 β π π = 9 32π + 11 β 32π + 11
=8
4 Conclusion
32π
=4 2
32π
?
Bro Tip: For divisibility proofs, find the difference, and
show thatβs divisible by what weβre interested in. This is
similar to how for summation proofs we isolated the
difference in the sum relative to the previous summation.
β΄ π π + 1 = π π + 4 2 32π
Therefore π(π) is divisible by 4 when π = π + 1.
Since true for π = 1 and if true for π = π, true for π = π + 1 for all π
?
β β€+ , therefore true for all integers.
Test Your Understanding
Step 1: Basis:
Step 2: Assumption:
Step 3: Inductive:
Step 4: Conclusion:
Prove the general statement is true for π = 1.
Assume the general statement is true for π = π.
Show that the general statement is then true for π = π + 1.
The general statement is then true for all positive integers π.
Prove by induction that π3 β 7π + 9 is divisible by 3 for all positive integers π.
1 Basis Step
Let π π = π3 β 7π + 9, where π β β€+ .
π 1 = 3 which is divisible by 3. ?
2 Assumption
Assume that for π = π, π π = π 3 β 7π + 9 is divisible by 3 for π
?
β β€+ .
π π+1 = π+1 3β7 π+1 +9
=β―
= π 3 + 3π 2 β 4π + 3
β΄ π π + 1 β π π = β― = 3 π2 ?
+πβ2
β΄ π π + 1 = π π + 3 π2 + π β 2
Therefore π(π) is divisible by 3 when π = π + 1.
3 Inductive
4 Conclusion
Since true for π = 1 and if true for π = π, true for π = π + 1 for all π
? by induction.
β β€+ , therefore true for all integers
Exercise 6B
Page 130.
All questions.
Type 3: Recurrence Relation Proofs
Step 1: Basis:
Step 2: Assumption:
Step 3: Inductive:
Step 4: Conclusion:
Prove the general statement is true for π = 1.
Assume the general statement is true for π = π.
Show that the general statement is then true for π = π + 1.
The general statement is then true for all positive integers π.
Notice that weβre trying
to prove a position-toterm formula from a
term-to-term one.
Given that π’π+1 = 3π’π + 4 and π’1 = 1, prove by induction that π’π = 3π β 2
1 Basis Step
When π = 1, π’1 = 31 β 2 = 1 as given.
?
IMPORTANT NOTE: The textbook gets this wrong (bottom of Page 131),
saying that ππ is required. I checked a mark scheme β it isnβt.
2 Assumption
Assume that for π = π, π’π = 3π β 2 is true for π β β€+ .
3 Inductive
Then π’π+1 = 3π’π + 4
4 Conclusion
Since true for π = 1 and if true for π = π, true for π = π + 1 for all π
?
β β€+ , therefore true for all integers.
?
= 3 3π β 2 + 4
= 3π+1?β 6 + 4
= 3π+1 β 2
This type of proof is slightly different to a summation proof, because
weβre using some given statement (the recurrence) to prove another,
whereas before we only had one statement.
Test Your Understanding
Edexcel FP1 Jan 2011
?
Recurrence Relations based on two previous terms
Step 1: Basis:
Step 2: Assumption:
Step 3: Inductive:
Step 4: Conclusion:
Prove the general statement is true for π = 1.
Assume the general statement is true for π = π.
Show that the general statement is then true for π = π + 1.
The general statement is then true for all positive integers π.
Given that π’π+2 = 5π’π+1 β 6π’π and π’1 = 13, π’2 = 35, prove by induction that
π’π = 2π+1 + 3π+1
1 Basis Step
When π = 1, π’1 = 22 + 32 = 13 as given.
When π = 2, π’2 = 23 + 33 = 35 as
? given.
We have two base cases so had to check 2 terms!
2 Assumption
Assume that for π = π and π = π + 1, π’π = 2π+1 + 3π+1 and π’π+1
= 2π+2 + 3π+2 is true for π β β€+ . ?
We need two previous instances of
3 Inductive
Then π’π+2 = 5π’π+1 β 6π’π
= 5 2π+1 + 3π+1 β 6 2π+1 + 3π+1
?
=β―
= 2π+3 + 3π+3
= 2π+2+1 + 3π+2+1
4 Conclusion
Since true for π = 1 and π = 2 and if true for π = π and π = π + 1,
true for π = π + 2 for all π β β€+ , ?
therefore true for all integers.
π in our assumption case now.
Exercise 6C
Page 132.
Q1, 3, 5, 7
Type 4: Matrix Proofs
Step 1: Basis:
Step 2: Assumption:
Step 3: Inductive:
Step 4: Conclusion:
Prove the general statement is true for π = 1.
Assume the general statement is true for π = π.
Show that the general statement is then true for π = π + 1.
The general statement is then true for all positive integers π.
1
Prove by induction that
0
1 Basis Step
2 Assumption
3 Inductive
4 Conclusion
β1
3
π
1
=
0
1 β 2π
for all π β β€+ .
π
2
1 β1 1
1 β1
When π = 1, πΏπ»π =
=
0 3
0 2
1
1 β1 ?
π
π»π = 1 1 β12 =
. As πΏπ»π = π
π»π, true for π = 1.
0
2
0
2
π
1 β1 π
1
1
β
2
Assume true π = π, i.e.
=
0 3 ?
0
2π
When π = π + 1,
π
1 β1 π+1
1 β1 π 1 β1
1
1
β
2
=
=
0 3
0 3
0 3
0
2π
π+1
?
1
1
β
2
=β―=
π+1
0
2
Therefore true when π = π + 1.
1
0
β1
3
Since true for π = 1 and if true for π = π, true for π = π + 1 for all π
? by induction.
β β€+ , therefore true for all integers
Test Your Understanding
Step 1: Basis:
Step 2: Assumption:
Step 3: Inductive:
Step 4: Conclusion:
Prove the general statement is true for π = 1.
Assume the general statement is true for π = π.
Show that the general statement is then true for π = π + 1.
The general statement is then true for all positive integers π.
β2 9
Prove by induction that
β1 4
1 Basis Step
2 Assumption
3 Inductive
4 Conclusion
π
=
β3π + 1
9π
for all π β β€+ .
βπ
3π + 1
β2 9 1
β2 9
When π = 1, πΏπ»π =
=
β1 4
β1 4
β3 + 1
9
β2 ? 9
π
π»π =
=
. As πΏπ»π = π
π»π, true for π = 1.
β1
3+1
β1 4
β2 9 π
β3π + 1
9π
Assume true π = π, i.e.
=
βπ
3π + 1
β1 4 ?
When π = π + 1,
β2 9 π+1
β2 9 π β2 9
β3π + 1
9π
β2 9
=
=
βπ
3π + 1 β1 4
β1 4
β1 4
β1 4
β3
? π + 1 + 1 9(π + 1)
β3π β 2 9π + 9
=β―=
=
β(π + 1)
3 π+1 +1
βπ β 1 3π + 4
Therefore true when π = π + 1.
Since true for π = 1 and if true for π = π, true for π = π + 1 for all π
? by induction.
β β€+ , therefore true for all integers
Exercise 6D
Page 134.
All questions.