Resolvable Mendelsohn designs and finite Frobenius groups

Abstract

We prove the existence and give constructions of a (p(k)-1)-fold perfect resolvable (v, k, 1)-Mendelsohn design for any integers v > k 2 with v 1 k such that there exists a finite Frobenius group whose kernel K has order v and whose complement contains an element φ of order k, where p(k) is the least prime factor of k. Such a design admits K φ as a group of automorphisms and is perfect when k is a prime. As an application we prove that for any integer v = p1e1 … ptet 3 in prime factorization, and any prime k dividing piei - 1 for 1 i t, there exists a resolvable perfect (v, k, 1)-Mendelsohn design that admits a Frobenius group as a group of automorphisms. We also prove that, if k is even and divides pi - 1 for 1 i t, then there are at least (k)t resolvable (v, k, 1)-Mendelsohn designs that admit a Frobenius group as a group of automorphisms, where is Euler's totient function.