I was provided with this code

```
m0=0.8;
m1=1.2;
k=6; %where k can take values between 2 and 10;
kbar=2^k;
g_m = [0:(kbar-1)];
for i = 1: (kbar)
g=1;
for j=0:(kbar-1)
if(bitand(g_m(i),2^j))~=0
g=g*m1;
else
g=g*m0;
end
end
g_m(i)=g %results in a 1xN vector where N = all the possible states
end
```

My question is why the function of `bitand`

allows you to generate all the possible "states"?
I am not too sure if I really understand the logic behind bitand beside searching if the values that it compares have a `bit = 1`

, hence `ans=1`

.

`kbar`

? – Paul R Jul 11 '12 at 9:18`|edit|`

link above. – Paul R Jul 11 '12 at 17:22`k`

between 2 and 10, then`kbar = 2^k`

– Plug4 Jul 11 '12 at 18:07