Let G be a group. G is supersolvable if there exists a normal series

${\displaystyle \{1\}=H_{0}\triangleleft H_{1}\triangleleft \cdots \triangleleft H_{s-1}\triangleleft H_{s}=G}$ 

such that each quotient group ${\displaystyle H_{i+1}/H_{i}\;}$  is cyclic and each ${\displaystyle H_{i}}$  is normal in ${\displaystyle G}$ .

By contrast, for a solvable group the definition requires each quotient to be abelian. In another direction, a polycyclic group must have a subnormal series with each quotient cyclic, but there is no requirement that each ${\displaystyle H_{i}}$  be normal in ${\displaystyle G}$ . As every finite solvable group is polycyclic, this can be seen as one of the key differences between the definitions. For a concrete example, the alternating group on four points, ${\displaystyle A_{4}}$ , is solvable but not supersolvable.

Some facts about supersolvable groups:

• Supersolvable groups are always polycyclic, and hence solvable.
• Every finitely generated nilpotent group is supersolvable.
• Every metacyclic group is supersolvable.
• The commutator subgroup of a supersolvable group is nilpotent.
• Subgroups and quotient groups of supersolvable groups are supersolvable.
• A finite supersolvable group has an invariant normal series with each factor cyclic of prime order.
• In fact, the primes can be chosen in a nice order: For every prime p, and for π the set of primes greater than p, a finite supersolvable group has a unique Hall π-subgroup. Such groups are sometimes called ordered Sylow tower groups.
• Every group of square-free order, and every group with cyclic Sylow subgroups (a Z-group), is supersolvable.
• Every irreducible complex representation of a finite supersolvable group is monomial, that is, induced from a linear character of a subgroup. In other words, every finite supersolvable group is a monomial group.
• Every maximal subgroup in a supersolvable group has prime index.
• A finite group is supersolvable if and only if every maximal subgroup has prime index.
• A finite group is supersolvable if and only if every maximal chain of subgroups has the same length. This is important to those interested in the lattice of subgroups of a group, and is sometimes called the Jordan–Dedekind chain condition.
• By Baum's theorem, every supersolvable finite group has a DFT algorithm running in time O(n log n).^{[clarification needed]}

• Schenkman, Eugene. Group Theory. Krieger, 1975.
• Schmidt, Roland. Subgroup Lattices of Groups. de Gruyter, 1994.
• Keith Conrad, SUBGROUP SERIES II, Section 4 , http://www.math.uconn.edu/~kconrad/blurbs/grouptheory/subgpseries2.pdf