Lucas' Theorem
Let be a prime. If is the base representation of and is the base representation of , where , Lucas' Theorem states that
Lemma
For prime and ,
Proof
For all , . Then we have that
Assume we have . Then
&\equiv&\left((1+x)^{p^k}\right)^p\\ &\equiv&\left(1+x^{p^k}\right)^p\\ &\equiv&\binom{p}{0}+\binom{p}{1}x^{p^k}+\binom{p}{2}x^{2p^k}+\cdots+\binom{p}{p-1}x^{(p-1)p^k}+\binom{p}{p}x^{p^{k+1}}\\
&\equiv&1+x^{p^{k+1}}\pmod{p}\end{eqnarray*}$ (Error compiling LaTeX. Unknown error_msg)Proof
Consider the . If is the base representation of , then for all and . We have
&=&[(1+x)^{p^m}]^{n_m}[(1+x)^{p^{m-1}}]^{n_{m-1}}\cdots[(1+x)^p]^{n_1}(1+x)^{n_0}\\ &\equiv&(1+x^{p^m})^{n_m}(1+x^{p^{m-1}})^{n_{m-1}}\cdots(1+x^p)^{n_1}(1+x)^{n_0}\pmod{p}
\end{eqnarray*}$ (Error compiling LaTeX. Unknown error_msg)We want the coefficient of in . Since , we want the coefficient of . The coefficient of each comes from the binomial expansion of , which is . Therefore we take the product of all such , and thus we have Note that . This is equivalent to saying that there is no term in the expansion of .