Searching for Disjoint Covering Systems with Precisely One Repeated Modulus

Abstract

A set of arithmetical sequences a1\, ( \,\, m1) , a2 \, (\,\, m2) , … , ak \, (\,\,mk) , with m1 ≤ m2 ≤ … ≤ mk , is called a disjoint covering system (alias exact covering system) if every positive integer belongs to exactly one of the sequences. Mirski, Newman, Davenport and Rado famously proved that the moduli can't all be distinct. In fact the two largest moduli must be equal, i.e. mk-1=mk This raises the natural question:"How close can you get to getting distinct moduli?", in other words, can you find all such systems where all the moduli are distinct except the largest, that is repeated r times, for any, specific given r? It turns out (conjecturally, but almost certainly) that excluding the trivial case where the smallest modulus is 2, for any number of repeats r, there are only finitely many such systems. Marc Berger, Alexander Felzenbaum and Aviezri Fraenkel found them all for r up to 9, and Mekmamu Zeleke and Jamie Simpson extended the list for systems up to 12 repeats. In the present article we continue the list up to r=32. All our systems are correct, but we did not bother to formally prove completeness, but we know for sure that the lists are complete if the largest modulus is ≤ 600, and we are pretty sure that they are complete.