Burnside's basis theorem

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Statement

Symbolic statement

Let $P$ be a $p$ -group for some prime $p$ , and let $Φ (P)$ denote the Frattini subgroup of $P$ . Then, $P / Φ (P)$ is the largest elementary Abelian quotient of $P$ , and hence is a vector space over the prime field $F_{p}$ .

Burnside's basis theorem states that:

A subset $S$ of $P$ is a generating set for $P$ iff the image of $S$ in $P / Φ (P)$ generates $P / Φ (P)$ as a $F_{p}$ -vector space.
A subset $S$ of $P$ is a minimal generating set for $P$ iff the image of $S$ in $P / Φ (P)$ is a vector space basis for $P / Φ (P)$ .

Related results

Burnside's basis theorem closely parallels certain formulations, and corollaries, of Nakayama's lemma, which states that generating sets for a module are in correspondence with generating sets for its top, which is its quotient by its Jacobson radical. Here, the Jacobson radical of a module plays the role of the Frattini subgroup, as the set of nongenerators.

Proof

The proof follows directly from the following two facts:

Combining a generating set for a normal subgroup, and a set of inverse images (via the quotient map) of the quotient group gives us a generating set for the quotient group
Any element in the Frattini subgroup can be dropped from any generating set.