3003 occurs twice in its own row, twice in row 78 and twice in rows 14 and 15. $$ \binom{3003}{1} = \binom{78}{2} = \binom{15}{5} = \binom{14}{6} $$ Additionally, it’s the only number known to appear 8 or more times. There are also no known integers which occur in the triangle exactly five or seven times. To prove the $O( \log a)$ bound we start by defining $N(a)$ as the number of solutions of $a=\binom{i+j}{j}=\binom{i+j}{i}$ , with $i,j \geq 1$ (since Pascal's triangle is symmetrical along its central column). Since, $\binom{i+j}{i}$ increases in each of $i$ and $j$ (in other words, if you pick a diagonal and follow it down or pick a column and follow it down the binomial coefficients will always increase), any choice of $i$ or $j$ admits a new solution value for $N(a)$. Now let's suppose that $a$ satisfies $a \leq \binom{2b}{b}$ implies that $i$ or $j < b$, so the solution count $N(a)≤ 2b$. Take the least such $b$. Then $2^{b-1} ≤\binom{2(b−1)}{b−1}≤ a$, $b ≤1+\log_2 a$, and $N(a) ≤ 2 + 2 \log_2 a = O(\log a)$ In 2007, Daniel Kane, a mathematician from Harvard, was able to [improve the result and the current best bound](http://www.emis.de/journals/INTEGERS/papers/h53/h53.pdf) is: $$ N(t) = O\big(\frac{(\log t)(\log \log \log t)}{ (\log \log \ t)^2} \big) $$ This paper is about the Sigmaster's Conjecture, which to this day still remains unsolved. The author, David Singmaster, is an American mathematician who is known for is mathematical puzzles as well as for his mathematical analysis of Rubik's Cube.  To understand his conjecture let's first talk about Pascal's Triangle. Pascal's triangle is a number triangle with numbers arranged in staggered rows such that each number is the sum of the two numbers above (starting with 1) and also a binomial coefficient. His conjecture states that we can find a number $a$, so that no value occurs in Pascal’s triangle more than $a$ times ($a \neq 1$). $$ N(a)< \infty $$