As part of my master thesis, I get a number (e.g. 5 bits) with 2 significant bits (2nd and 4th). This means for example `x1x0x`

, where `$x \in {0,1}$`

(x could be 0 or 1) and `1,0`

are bits with fixed values.

My first task is to compute all the combinations of the above given number , `2^3 = 8`

. This is called `S_1`

group.

Then I need to compute 'S_2' group and this is all the combinations of the two numbers `x0x0x`

and `x1x1x`

(this means one mismatch in the significant bits), this should give us `$\bin{2}{1} * 2^3 = 2 * 2^3 = 16`

.

**EDIT**
Each number, `x1x1x`

and `x0x0x`

, is different from the *Original* number, `x1x0x`

, at one significant bit.

Last group, `S_3`

, is of course two mismatches from the significant bits, this means, all the numbers which pass the form `x0x1x`

, 8 possibilities.

The computation could be computed recursively or independently, that is not a problem.

I would be happy if someone could give a starting point for these computations, since what I have is not so efficient.

**EDIT**
Maybe I chose my words wrongly, using *significant bits*. What I meant to say is that a specific places in a five bits number the bit are fixed. Those places I defined as *specific bits*.

**EDIT**
I saw already 2 answers and it seems I should have been clearer. What I am more interested in, is finding the numbers `x0x0x`

, `x1x1x`

and `x0x1x`

with respect that this is a simply example. In reality, the group `S_1`

(in this example `x1x0x`

) would be built with at least 12 bit long numbers and could contain 11 significant bits. Then I would have 12 groups...

If something is still not clear please ask ;)

end goalof all of this? – Puppy Feb 22 '11 at 19:01