It is based on the fact that numbers are coded in binary.

If the number A is an integer, A is rewritten as A=∑_{i=0}^{n-1}a_{i}×2^{i}=a_{n-1}×2^{n-1}+a_{n-2}×2^{n-2}+...+a_{1}×2+a_{0}

where a_{i}=0 or 1.

It is easy to see that is A is even, a_{0}=0, and if it is odd, a_{0}=1. So we already have the least significant bit a_{0}.

Now, if we divide A by two, a_{0} disappears and we have
A/2=a_{n-1}×2^{n-2}+a_{n-2}×2^{n-3}+...+a_{2}×2+a_{1}

We can determine this way a_{1} depending on the parity of A/2. and we continue, we get all the bits of A.

Fractional numbers are expressed according to negative powers of 2. If A=0.a_{-1}a_{-2}...a_{-n}, A=a_{-1}/2+a_{-2}/4+...+a_{-n}/2^^{n}

If we multiply it by two, 2×A=a_{-1}+a_{-2}/2+...+a_{-n}/2^^{n-1}. If 2×A≥1, we must have a-1=1, otherwise a-1=0. And we can determine other bits is a similar way by successive multiplications by two.