Let H₁, H₂, ... H_n be subgroups of Group G with operation ${\displaystyle \ast }$

${\displaystyle H_{1}\cap H_{2}\cap \cdots \cap H_{n}}$ with ${\displaystyle \ast }$ is a subgroup of Group G

1. ${\displaystyle H_{1}\subseteq G}$	H1 is subgroup of G
2. ${\displaystyle H_{2}\subseteq G}$	H2 is subgroup of G
3. ${\displaystyle (H_{1}\cap H_{2})\subseteq G}$	1. and 2.

4. Choose ${\displaystyle x,y\in (H_{1}\cap H_{2})}$
5. ${\displaystyle x\ast y\in H_{1}}$	closure of H1
6. ${\displaystyle x\ast y\in H_{2}}$	closure of H2
7. ${\displaystyle x\ast y\in (H_{1}\cap H_{2})}$	5. and 6.

8. ${\displaystyle \ast }$ is associative on G.	Group G's operation is ${\displaystyle \ast }$
9. ${\displaystyle (H_{1}\cap H_{2})\subseteq G}$	3.
10. ${\displaystyle \ast }$ is associative on ${\displaystyle (H_{1}\cap H_{2})}$	8. and 9.

11. ${\displaystyle e_{G}\in H_{1}}$ and ${\displaystyle e_{G}\in H_{2}}$	Subgroup H1 and H2 inherit identity from G
12. ${\displaystyle \forall g\in G:e_{G}\ast g=g\ast e_{G}=g}$	eG is identity of G,
13. ${\displaystyle \forall \;g\in (H_{1}\cap H_{2}):e_{G}\ast g=g\ast e_{G}=g}$	${\displaystyle (H_{1}\cap H_{2})\subseteq G}$ and 9.
14. ${\displaystyle (H_{1}\cap H_{2})}$ has identity eG	definition of identity

15. Choose ${\displaystyle g\in (H_{1}\cap H_{2})\subseteq G}$
16. ${\displaystyle g\in H_{1}}$, ${\displaystyle g\in H_{2}}$, and ${\displaystyle g\in G}$
17. gH1−1 in H1, and gH2−1 in H2.	G, H1, and H2 are groups
18. ${\displaystyle g_{H1}^{-1}\in G}$	${\displaystyle H_{1}\subseteq G}$
19. ${\displaystyle g_{H1}^{-1}\ast g=g\ast g_{H1}^{-1}=e_{G}}$	G and H1 shares identity e
20. gH1−1 is inverse of g in G	19. and definition of inverse
21. Let gG−1 be inverse of g has in G
22. gG−1 = gH1−1	inverse is unique
22. gG−1 = gH2−1	similar to 21.
23. ${\displaystyle g^{-1}=g_{H1}^{-1}=g_{H2}^{-1}\in (H_{1}\cap H_{2})}$
24. g has inverse g−1 in ${\displaystyle (H_{1}\cap H_{2})}$