According to the ErdH{o}s discrepancy conjecture, for any infinite $pm 1$ sequence, there exists a homogeneous arithmetic progression of unbounded discrepancy. In other words, for any $pm 1$ sequence $(x_1,x_2,...)$ and a discrepancy $C$, there exist
integers $m$ and $d$ such that $|sum_{i=1}^m x_{i cdot d}| > C$. This is an $80$-year-old open problem and recent development proved that this conjecture is true for discrepancies up to $2$. Paul ErdH{o}s also conjectured that this property of unbounded discrepancy even holds for the restricted case of completely multiplicative sequences (CMSs), namely sequences $(x_1,x_2,...)$ where $x_{a cdot b} = x_{a} cdot x_{b}$ for any $a,b geq 1$. The longest CMS with discrepancy $2$ has been proven to be of size $246$. In this paper, we prove that any completely multiplicative sequence of size $127,646$ or more has discrepancy at least $4$, proving the ErdH{o}s discrepancy conjecture for CMSs of discrepancies up to $3$. In addition, we prove that this bound is tight and increases the size of the longest known sequence of discrepancy $3$ from $17,000$ to $127,645$. Finally, we provide inductive construction rules as well as streamlining methods to improve the lower bounds for sequences of higher discrepancies.
