My professor gave an example located on slide 3 of this pdf: can anybody explain to me how he ended up with m_n = 2^(n) - 1. Thanks!
4 Answers
The step is from
mn =2n−1 +2n−2 +...+22 +2+1.
to
mn = 2n − 1
There are two ways to make the step. One is to recognize this as a geometric series, and know the rule:
sum=(1-rn)/(1-r)
The other is to have played around enough with powers of two to know that if you add up a bunch of them starting from 1, you get the next one, minus one.
There is a formula for the sum of the first n terms of a geometric series.
1 + 2 + 2^2 + 2^3 + ... + 2^{n-1}
= (1 - 2^n) / (1 - 2)
= (1 - 2^n) / (-1)
= 1/(-1) - 2^n/(-1)
= 2^n - 1
It's just one of the relations of series that people have figured out over the years:
2^(n-1) + 2^(n-2) + ... + 2 + 1 == 2^n - 1
You can think of it a lot like the sum of binary numbers:
000001
000010
000100
001000
+ 010000
------
011111 == 1000000 - 1
Actually,
Mn=2^0+2^1+.........+2^(n-1)+2^(n-2)
is the Nth
term of the sequence Mk=.....
And this Nth
term itself is a sum of a geometrical progression whose 1st term is 1(2^0)
and common ratio=2
.
And this sum(Mn)
is
=a[(r^n)-1]/[r-1]
where a is 1st term and r common ratio
=1*[(2^n)-1]/[2-1]
Mn=2^n - 1