Mathematical Induction is a special way of proving things. It has only 2 steps:

• Step 1. Show it is true for the first one
• Step 2. Show that if any one is true then the next one is true

Then all are true

Example: 3ⁿ−1 is a multiple of 2

Is that true? Let us find out.

1. Show it is true for n=1

3¹−1 = 3−1 = 2

Yes 2 is a multiple of 2. That was easy.

3¹−1 is true

2. Assume it is true for n=k

3^k−1 is true

(Hang on! How do we know that? We don't!
It is an assumption ... that we treat
as a fact for the rest of this example)

Now, prove that 3^k+1−1 is a multiple of 2

3^k+1 is also 3×3^k

And then split 3× into 2× and 1×

And each of these are multiples of 2

Because:

• 2×3^k is a multiple of 2 (we are multiplying by 2)
• 3^k−1 is true (we said that in the assumption above)

So:

3^k+1−1 is true

DONE!

A common trick is to rewrite the n=k+1 case into 2 parts:

• one part being the n=k case (which is assumed to be true)
• the other part can then be checked to see if it is also true

Example: Adding up Odd Numbers

1 + 3 + 5 + ... + (2n−1) = n²

1. Show it is true for n=1

1 = 1² is True

2. Assume it is true for n=k

1 + 3 + 5 + ... + (2k−1) = k² is True
(An assumption!)

Now, prove it is true for "k+1"

1 + 3 + 5 + ... + (2k−1) + (2(k+1)−1) = (k+1)²   ?

We know that 1 + 3 + 5 + ... + (2k−1) = k² (the assumption above), so we can do a replacement for all but the last term:

k² + (2(k+1)−1) = (k+1)²

Now expand all terms:

k² + 2k + 2 − 1 = k² + 2k+1

And simplify:

k² + 2k + 1 = k² + 2k + 1

They are the same! So it is true.

So:

1 + 3 + 5 + ... + (2(k+1)−1) = (k+1)² is True

DONE!