Isodynamic point

Goursat's lemma is an algebraic theorem about subgroups of the direct product of two groups.

It can be stated as follows.

Let ${\displaystyle G}$, ${\displaystyle G^{\prime }}$ be groups, and let ${\displaystyle H}$ be a subgroup of ${\displaystyle G\times G^{\prime }}$ such that the two projections ${\displaystyle p_1:H\to G}$ and ${\displaystyle p_2:H\to G^{\prime }}$ are surjective (i.e., ${\displaystyle H}$ is a subdirect product of ${\displaystyle G}$ and ${\displaystyle G^{\prime }}$). Let ${\displaystyle N}$ be the kernel of ${\displaystyle p_2}$ and ${\displaystyle N^{\prime }}$ the kernel of ${\displaystyle p_1}$. One can identify ${\displaystyle N}$ as a normal subgroup of ${\displaystyle G}$, and ${\displaystyle N^{\prime }}$ as a normal subgroup of ${\displaystyle G^{\prime }}$. Then the image of ${\displaystyle H}$ in ${\displaystyle G/N\times G^{\prime }/N^{\prime }}$ is the graph of an isomorphism ${\displaystyle G/N\approx G^{\prime }/N^{\prime }}$.

An immediate consequence of this is that the subdirect product of two groups can be described as a fiber product and vice versa.

Proof of Goursat's lemma

Before proceeding with the proof, ${\displaystyle N}$ and ${\displaystyle N^{\prime }}$ are shown to be normal in ${\displaystyle G\times \{e^{\prime }\}}$ and ${\displaystyle \{e\}\times G^{\prime }}$, respectively. It is in this sense that ${\displaystyle N}$ and ${\displaystyle N^{\prime }}$ can be identified as normal in G and G', respectively.

Since ${\displaystyle p_2}$ is a homomorphism, its kernel N is normal in H. Moreover, given ${\displaystyle g\in G}$, there exists ${\displaystyle h=(g,g^{\prime })\in H}$, since ${\displaystyle p_1}$ is surjective. Therefore, ${\displaystyle p_1(N)}$ is normal in G, viz:

${\displaystyle g{p}_1(N)=p_1(h)p_1(N)=p_1(hN)=p_1(Nh)=p_1(N)g}$.

It follows that ${\displaystyle N}$ is normal in ${\displaystyle G\times \{e^{\prime }\}}$ since

${\displaystyle (g,e^{\prime })N=(g,e^{\prime })(p_1(N)\times \{e^{\prime }\})=g{p}_1(N)\times \{e^{\prime }\}=p_1(N)g\times \{e^{\prime }\}=(p_1(N)\times \{e^{\prime }\})(g,e^{\prime })=N(g,e^{\prime })}$.

The proof that ${\displaystyle N^{\prime }}$ is normal in ${\displaystyle \{e\}\times G^{\prime }}$ proceeds in a similar manner.

Given the identification of ${\displaystyle G}$ with ${\displaystyle G\times \{e^{\prime }\}}$, we can write ${\displaystyle G/N}$ and ${\displaystyle gN}$ instead of ${\displaystyle (G\times \{e^{\prime }\})/N}$ and ${\displaystyle (g,e^{\prime })N}$, ${\displaystyle g\in G}$. Similarly, we can write ${\displaystyle G^{\prime }/N^{\prime }}$ and ${\displaystyle g^{\prime }{N}^{\prime }}$, ${\displaystyle g^{\prime }\in G^{\prime }}$.

On to the proof. Consider the map ${\displaystyle H\to G/N\times G^{\prime }/N^{\prime }}$ defined by ${\displaystyle (g,g^{\prime })\mapsto (gN,g^{\prime }{N}^{\prime })}$. The image of ${\displaystyle H}$ under this map is ${\displaystyle \{(gN,g^{\prime }{N}^{\prime })|(g,g^{\prime })\in H\}}$. This relation is the graph of a well-defined function ${\displaystyle G/N\to G^{\prime }/N^{\prime }}$ provided ${\displaystyle gN=N\Rightarrow g^{\prime }{N}^{\prime }=N^{\prime }}$, essentially an application of the vertical line test.

Since ${\displaystyle gN=N}$ (more properly, ${\displaystyle (g,e^{\prime })N=N}$), we have ${\displaystyle (g,e^{\prime })\in N\subset H}$. Thus ${\displaystyle (e,g^{\prime })=(g,g^{\prime })(g^{-1},e^{\prime })\in H}$, whence ${\displaystyle (e,g^{\prime })\in N^{\prime }}$, that is, ${\displaystyle g^{\prime }{N}^{\prime }=N^{\prime }}$. Note that by symmetry, it is immediately clear that ${\displaystyle g^{\prime }{N}^{\prime }=N^{\prime }\Rightarrow gN=N}$, i.e., this function also passes the horizontal line test, and is therefore one-to-one. The fact that this function is a surjective group homomorphism follows directly.

References

• Kenneth A. Ribet (Autumn 1976), "Galois Action on Division Points of Abelian Varieties with Real Multiplications", American Journal of Mathematics, Vol. 98, No. 3, 751–804.