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Kiwi1
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I have answered Q1-Q3. I am unsure of my answer for Q4 and am stuck on Q5.
Notation: \(I^*=Gal(K:I)\). That is the subgroup of G=Gal(K:F) that fixes I.
Q4.
I2 is conjugate to I1.
iff \(\exists i \in G:I_2=i(I_1)\)
iff \( I^*_2=[i(I_1)]^*=iI_1^*i^{-1}\) by Q3.
iff \( I^*_2=iI_1^*i^{-1}\)
iff \( I^*_2=\phi_i(I_1^*)\) where \(\phi_i\) is the function conjugate by i.
iff \(I_1^*\) is conjugate to \(I_2^*\)
Q5. I have lots of ideas but keep going in circles.
Suppose \(I_2\) is a normal extension of \(I_1\) then
\(I_2\) is the root field of some a(x) over \(I_1\)
and we have the isomorphism \(\phi \) defined by:
\(I_2 \cong \frac{I_1[x]}{<a(x)>}\)
Now I gloss over the fact that phi is an isomorphism when I need an automorphism. I take phi to mean that I_1 and I_2 are conjugate. Therefore using Q4 \(I^*_2\) and the fixer of the RHS of my isomorphism are conjugate. That is there exists an automorphism pi such that:
\(I_2^* \cong \left(\frac{I_1[x]}{<a(x)>}\right)^*\)
again I am glossing over the difference between isomorphism and automorphism.
Now since these two fixers are conjugate I can write
there exists \(x \in I_1\) such that \(I^*_2 \cong x \left(\frac{I_1[x]}{<a(x)>}\right)^* x^{-1}\)
Now x and \(x^{-1}\) both fix the coefficients of a(x) and \(I_1^*[x]\) so:
there exists \(x \in I_1\) such that \(I^*_2 \cong \left(\frac{I_1[x]}{<a(x)>}\right)^* \)
So \(I^*_2\) is a normal subgroup of \(I^*_1\)
I know I have 'cheated' at various points but am I on the right track to finding a solution? I need to reverse the order of my argument so that this argument complements Q1.
I have answered Q1-Q3. I am unsure of my answer for Q4 and am stuck on Q5.
Notation: \(I^*=Gal(K:I)\). That is the subgroup of G=Gal(K:F) that fixes I.
Q4.
I2 is conjugate to I1.
iff \(\exists i \in G:I_2=i(I_1)\)
iff \( I^*_2=[i(I_1)]^*=iI_1^*i^{-1}\) by Q3.
iff \( I^*_2=iI_1^*i^{-1}\)
iff \( I^*_2=\phi_i(I_1^*)\) where \(\phi_i\) is the function conjugate by i.
iff \(I_1^*\) is conjugate to \(I_2^*\)
Q5. I have lots of ideas but keep going in circles.
Suppose \(I_2\) is a normal extension of \(I_1\) then
\(I_2\) is the root field of some a(x) over \(I_1\)
and we have the isomorphism \(\phi \) defined by:
\(I_2 \cong \frac{I_1[x]}{<a(x)>}\)
Now I gloss over the fact that phi is an isomorphism when I need an automorphism. I take phi to mean that I_1 and I_2 are conjugate. Therefore using Q4 \(I^*_2\) and the fixer of the RHS of my isomorphism are conjugate. That is there exists an automorphism pi such that:
\(I_2^* \cong \left(\frac{I_1[x]}{<a(x)>}\right)^*\)
again I am glossing over the difference between isomorphism and automorphism.
Now since these two fixers are conjugate I can write
there exists \(x \in I_1\) such that \(I^*_2 \cong x \left(\frac{I_1[x]}{<a(x)>}\right)^* x^{-1}\)
Now x and \(x^{-1}\) both fix the coefficients of a(x) and \(I_1^*[x]\) so:
there exists \(x \in I_1\) such that \(I^*_2 \cong \left(\frac{I_1[x]}{<a(x)>}\right)^* \)
So \(I^*_2\) is a normal subgroup of \(I^*_1\)
I know I have 'cheated' at various points but am I on the right track to finding a solution? I need to reverse the order of my argument so that this argument complements Q1.
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