Two-Step Subgroup Test

Theorem
Let $\struct {G, \circ}$ be a group.

Let $H$ be a subset of $G$.

Then $\struct {H, \circ}$ is a subgroup of $\struct {G, \circ}$ :


 * $(1): \quad H \ne \O$, that is, $H$ is non-empty
 * $(2): \quad a, b \in H \implies a \circ b \in H$
 * $(3): \quad a \in H \implies a^{-1} \in H$.

That is, $\struct {H, \circ}$ is a subgroup of $\struct {G, \circ}$ $\struct {H, \circ}$ is a $H$ be a nonempty subset of $G$ which is:
 * closed under its operation

and:
 * closed under inversion.

Necessary Condition
Let $H$ be a subset of $G$ that fulfils the conditions given.

It is noted that the fact that $H$ is nonempty is one of the conditions.

It is also noted that the group operation of $\struct {H, \circ}$ is the same as that for $\struct {G, \circ}$, that is, $\circ$.

So it remains to show that $\struct {H, \circ}$ is a group.

We check the four group axioms:

The closure condition is given by condition $(2)$.

From Restriction of Associative Operation is Associative, associativity is inherited by $\struct {H, \circ}$ from $\struct {G, \circ}$.

Let $e$ be the identity of $\struct {G, \circ}$.

From condition $(1)$, $H$ is non-empty.

Therefore $\exists x \in H$.

From condition $(3)$, $\struct {H, \circ}$ is closed under inversion.

Therefore $x^{-1} \in H$.

Since $\struct {H, \circ}$ is closed under $\circ$, $x \circ x^{-1} = e = x^{-1} \circ x \in H$.

From condition $(3)$, every element of $H$ has an inverse.

So $\struct {H, \circ}$ satisfies all the group axioms, and is therefore a group.

So by definition $\struct {H, \circ}$ is a subgroup of $\struct {G, \circ}$.

Sufficient Condition
Now suppose $\struct {H, \circ}$ is a subgroup of $\struct {G, \circ}$.


 * $(1): \quad H \le G \implies H \ne \O$ from the fact that $H$ is a group and therefore can not be empty.
 * $(2): \quad a, b \in H \implies a \circ b \in H$ follows from as applied to the group $\struct {H, \circ}$.
 * $(3): \quad a \in H \implies a^{-1} \in H$ follows from as applied to the group $\struct {H, \circ}$.

Also defined as
Some sources specify condition $(1)$ as being $e \in H$ in order to satisfy the non-emptiness condition, but from Identity of Subgroup it can be seen that this is not necessary, as this follows automatically by conditions $(2)$ and $(3)$.

Some sources completely omit to state the fact that $H$ needs to be non-empty.

Some sources, for example, use this property of subgroups as the definition of a subgroup, and from it deduce that a subgroup is a subset which is a group.

However, this definition is valid only if $\struct {G, \circ}$ is itself a group, as it is here so defined; it cannot be used to define a subgroup of a more general algebraic structure.

Also see

 * Two-Step Subgroup Test using Subset Product
 * One-Step Subgroup Test