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