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user267839
user267839
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That is we start with an arbitrary extension $0 \to M \to E \to L \to 0$$0 \to M \to e_2 \to L \to 0$ represented by the class of the image $\Phi_E:=\delta(id_L)$$\Phi_{e_2}:=\delta(id_L)$ with respect the delta-map in upperlower row in second diagram below and it's pullback extension $e_2$ in the upper row. Now we want to determine whichthat the extension $\overline{E}$$\overline{e_1}$ is represented by multiplication $a \cdot \Phi_E =: \Phi_{\overline{E}}$$a \cdot \Phi_{e_2} =: \Phi_{e_1}$.

We apply $Hom(L,-)$ to diagram

$$ \require{AMScd} \begin{CD} 0 @> >> M @> >> E @> >> L @> >> 0\\ @VVV @VVV @VVV @VV\cdot{a}V \\ 0 @> >> M @> >> \overline{E} @> >> L @> >> 0 \end{CD} $$$$ \require{AMScd} \begin{CD} 0 @> >> M @> >> e_1 @>a^{-1} >> L @> >> 0\\ @VVV @VVV @VVV @VV\cdot{a}V \\ 0 @> >> M @> >> e_2 @> >> L @> >> 0 \end{CD} $$

and obtain

$$ \require{AMScd} \begin{CD} Hom(L, E) @> >> Hom(L,L) @>\delta >> Ext(L,M) @> >> \\ @VVV @VV\cdot{a}V @VV\cdot{a}V \\ Hom(L,\overline{E}) @> >> Hom(L,L) @>\delta >> Ext(L,M) @> >> \end{CD} $$$$ \require{AMScd} \begin{CD} Hom(L, E) @> >> Hom(L,L) @>\delta >> Ext(L,M) @> >> \\ @VVV @VV\cdot{a}V @VVV \\ Hom(L,\overline{E}) @> >> Hom(L,L) @>\delta >> Ext(L,M) @> >> \end{CD} $$

That's a diagram of $k$-vector spaces. As you explaned in the answer the extension $E$$e_1$ is forced to be the pullback of $\overline{E}$$e_2$: i.e. $E= a^*\overline{E}$$e_1= a^*e_2$. This implies that $\overline{E}= (a^{-1})^*E$, thus$k$-linearity and commutativity of the maps imply $a \cdot \Phi_E = \Phi_{(a^{-1})^*E}$$a \cdot \Phi_{e_2}=a \cdot \delta(id_L) = \delta(a \cdot id_L) = \Phi_{e_1}$. So $e_1=a e_2$. Is this the correct result of the $k^*$ action by scalar multiplication on $Ext(L,M)$? Or do I have somewhere implemented your hints on my question 1) in wrong way?

That is we start with an arbitrary extension $0 \to M \to E \to L \to 0$ represented by the class of the image $\Phi_E:=\delta(id_L)$ with respect the delta-map in upper row in second diagram below and we want to determine which extension $\overline{E}$ is represented by $a \cdot \Phi_E =: \Phi_{\overline{E}}$.

We apply $Hom(L,-)$ to diagram

$$ \require{AMScd} \begin{CD} 0 @> >> M @> >> E @> >> L @> >> 0\\ @VVV @VVV @VVV @VV\cdot{a}V \\ 0 @> >> M @> >> \overline{E} @> >> L @> >> 0 \end{CD} $$

and obtain

$$ \require{AMScd} \begin{CD} Hom(L, E) @> >> Hom(L,L) @>\delta >> Ext(L,M) @> >> \\ @VVV @VV\cdot{a}V @VV\cdot{a}V \\ Hom(L,\overline{E}) @> >> Hom(L,L) @>\delta >> Ext(L,M) @> >> \end{CD} $$

That's a diagram of $k$-vector spaces. As you explaned in the answer the extension $E$ is forced to be the pullback of $\overline{E}$: i.e. $E= a^*\overline{E}$. This implies that $\overline{E}= (a^{-1})^*E$, thus $a \cdot \Phi_E = \Phi_{(a^{-1})^*E}$. Is this the correct result of the $k^*$ action by scalar multiplication on $Ext(L,M)$? Or do I have somewhere implemented your hints on my question 1) in wrong way?

That is we start with an arbitrary extension $0 \to M \to e_2 \to L \to 0$ represented by the class of the image $\Phi_{e_2}:=\delta(id_L)$ with respect the delta-map in lower row in second diagram below and it's pullback extension $e_2$ in the upper row. Now we want determine that the extension $\overline{e_1}$ is represented by multiplication $a \cdot \Phi_{e_2} =: \Phi_{e_1}$.

We apply $Hom(L,-)$ to diagram

$$ \require{AMScd} \begin{CD} 0 @> >> M @> >> e_1 @>a^{-1} >> L @> >> 0\\ @VVV @VVV @VVV @VV\cdot{a}V \\ 0 @> >> M @> >> e_2 @> >> L @> >> 0 \end{CD} $$

and obtain

$$ \require{AMScd} \begin{CD} Hom(L, E) @> >> Hom(L,L) @>\delta >> Ext(L,M) @> >> \\ @VVV @VV\cdot{a}V @VVV \\ Hom(L,\overline{E}) @> >> Hom(L,L) @>\delta >> Ext(L,M) @> >> \end{CD} $$

That's a diagram of $k$-vector spaces. As you explaned in the answer the extension $e_1$ is forced to be the pullback of $e_2$: i.e. $e_1= a^*e_2$. $k$-linearity and commutativity of the maps imply $a \cdot \Phi_{e_2}=a \cdot \delta(id_L) = \delta(a \cdot id_L) = \Phi_{e_1}$. So $e_1=a e_2$. Is this the correct result of the $k^*$ action by scalar multiplication on $Ext(L,M)$? Or do I have somewhere implemented your hints on my question 1) in wrong way?

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user267839
user267839
  • 6k
  • 2
  • 11
  • 42

That is we start with an arbitrary extension $0 \to M \to E \to L \to 0$ represented by the class of the image $\Phi_E:=\delta(id_L)$ with respect the delta-map in upper row in second diagram below and we want to determine which extension $\overline{E}$ is represented by $a \cdot \Phi_E =: \Phi_{\overline{E}}$.

We apply $Hom(L,-)$ to diagram

$$ \require{AMScd} \begin{CD} 0 @> >> M @> >> E @> >> L @> >> 0\\ @VVV @VVV @VVV @VV\cdot{a}V \\ 0 @> >> M @> >> \overline{E} @> >> L @> >> 0 \end{CD} $$

and obtain

$$ \require{AMScd} \begin{CD} Hom(L, E) @> >> Hom(L,L) @>\delta >> Ext(L,M) @> >> \\ @VVV @VV\cdot{a}V @VV\cdot{a}V \\ Hom(L,\overline{E}) @> >> Hom(L,L) @>\delta >> Ext(L,M) @> >> \end{CD} $$

That's a diagram of $k$-vector spaces. As you explaned in the answer the extension $E$ is forced to be the pullback of $\overline{E}$: i.e. $E= a^*\overline{E}$. This implies that $\overline{E}= (a^{-1})^*E$, thus $a \cdot \Phi_E = \Phi_{(a^{-1})^*E}$. Is this the correct result of the $k^*$ action by scalar multiplication on $Ext(L,M)$? Or do I have somewhere implemented your hints on my question 1) in wrong way?