Вернусь к объяснению первой части, так как получилось очень коряво.
(У меня нет подробных записей. Вся только контурно, пишу прямо из головы, потому и возможны бяки)
Обозначим для облегчения восприятия
![$\[e^{\frac{{2\pi l}}{{P}}} = \varphi\]$](https://dxdy-02.korotkov.co.uk/f/9/4/d/94dc2b3b2b5d49b959861e2c8dcf39e382.png "$\[e^{\frac{{2\pi l}}{{P}}} = \varphi\]$")
![$\[\left( {P - 1} \right)/3 = h\]$](https://dxdy-03.korotkov.co.uk/f/e/9/0/e90dbf6d42df63388899ac743febf1a482.png "$\[\left( {P - 1} \right)/3 = h\]$")
Имеем:
![$\[
\eta _{\left( P \right)} ^{\left( t \right)} = \sum\limits_{k = 1}^h {\varphi ^{g^{3k} t} } + \varepsilon \sum\limits_{k = 1}^h {\varphi ^{g^{3k + 1} t} } + \varepsilon ^2 \sum\limits_{k = 1}^h {\varphi ^{g^{3k + 2} t} }
\]$](https://dxdy-02.korotkov.co.uk/f/5/5/7/5579660cbe4619c55e2d26884b42661182.png "$\[
\eta _{\left( P \right)} ^{\left( t \right)} = \sum\limits_{k = 1}^h {\varphi ^{g^{3k} t} } + \varepsilon \sum\limits_{k = 1}^h {\varphi ^{g^{3k + 1} t} } + \varepsilon ^2 \sum\limits_{k = 1}^h {\varphi ^{g^{3k + 2} t} }
\]$")
Рассмотрим некоторый элемент из первой группы при изоморфизме
![$\[t_0 \]$](https://dxdy-01.korotkov.co.uk/f/4/7/5/47564f64aa01479a71cd491ae823f40a82.png "$\[t_0 \]$")
.
Пусть
![$\[
g^{3k} t_0 \equiv g^{3m} \left( {\bmod P} \right)
\]$](https://dxdy-03.korotkov.co.uk/f/6/3/9/63905c0a520595881404988b141d1b3382.png "$\[
g^{3k} t_0 \equiv g^{3m} \left( {\bmod P} \right)
\]$")
![$\[
t_0 \equiv g^{3m - 3k} \left( {\bmod P} \right)
\]$](https://dxdy-02.korotkov.co.uk/f/5/5/4/554a1acd56824165ee4a1370e860773482.png "$\[
t_0 \equiv g^{3m - 3k} \left( {\bmod P} \right)
\]$")
тогда дугой элемент из этой группы
![$\[
g^{3n} t_0 \equiv g^{3n} g^{3\left( {m - k} \right)} \equiv g^{3\left( {n + m - k} \right)} \equiv \left( {\bmod P} \right)
\]$](https://dxdy-03.korotkov.co.uk/f/2/5/4/254a18be36c0802172df2d430eedf9b482.png "$\[
g^{3n} t_0 \equiv g^{3n} g^{3\left( {m - k} \right)} \equiv g^{3\left( {n + m - k} \right)} \equiv \left( {\bmod P} \right)
\]$")
также будет принадлежать этой группе
Любой элемент из второй группе при этом же изоморфизме
![$\[
g^{3r + 1} t_0 \equiv g^{3r + 1} g^{3\left( {m - k} \right)} \equiv g^{3\left( {r + m - k} \right) + 1} \equiv \left( {\bmod P} \right)
\]$](https://dxdy-02.korotkov.co.uk/f/d/8/8/d88cd8d4a406ee51b6d6a4036d4be15b82.png "$\[
g^{3r + 1} t_0 \equiv g^{3r + 1} g^{3\left( {m - k} \right)} \equiv g^{3\left( {r + m - k} \right) + 1} \equiv \left( {\bmod P} \right)
\]$")
также будет принадлежать второй группе. Также и с третьей группой.
Т.е. общий вид выражения не изменится, только внутри групп элементы перемешаются.
Теперь, пусть при изоморфизме элемент первой группы станет элементом второй группы
![$\[
g^{3k} t_0 \equiv g^{3m + 1} \left( {\bmod P} \right)
\]$](https://dxdy-02.korotkov.co.uk/f/5/a/2/5a2ebd63ec123cb6db1b5f1a4261078a82.png "$\[
g^{3k} t_0 \equiv g^{3m + 1} \left( {\bmod P} \right)
\]$")
![$\[
t_0 \equiv g^{3\left( {m - k} \right) + 1} \left( {\bmod P} \right)
\]$](https://dxdy-02.korotkov.co.uk/f/1/5/0/15079212acb29c0bf9cb8ae82ba4556982.png "$\[
t_0 \equiv g^{3\left( {m - k} \right) + 1} \left( {\bmod P} \right)
\]$")
Тогда мы увидим, что все элементы первой группы станут элементами второй группы, все элементы второй группы станут элементами третьей, а элементы третьей элементами первой.
![$\[
\eta _{\left( P \right)} ^{\left( {t_0 } \right)} = \sum\limits_{k = 1}^h {\varphi ^{g^{3k + 2} } } + \varepsilon \sum\limits_{k = 1}^h {\varphi ^{g^{3k} } } + \varepsilon ^2 \sum\limits_{k = 1}^h {\varphi ^{g^{3k + 1} } } =
\]$](https://dxdy-02.korotkov.co.uk/f/d/a/1/da1bdc7f3a7882f95e95cad21f997eb882.png "$\[
\eta _{\left( P \right)} ^{\left( {t_0 } \right)} = \sum\limits_{k = 1}^h {\varphi ^{g^{3k + 2} } } + \varepsilon \sum\limits_{k = 1}^h {\varphi ^{g^{3k} } } + \varepsilon ^2 \sum\limits_{k = 1}^h {\varphi ^{g^{3k + 1} } } =
\]$")
![$\[
\varepsilon \left( {\varepsilon ^2 \sum\limits_{k = 1}^h {\varphi ^{g^{3k + 2} } } + \sum\limits_{k = 1}^h {\varphi ^{g^{3k} } } + \varepsilon \sum\limits_{k = 1}^h {\varphi ^{g^{3k + 1} } } } \right) = \varepsilon \eta _{\left( P \right)}
\]$](https://dxdy-01.korotkov.co.uk/f/8/4/c/84c6b6dc6b8307db4e5841e41cc1330b82.png "$\[
\varepsilon \left( {\varepsilon ^2 \sum\limits_{k = 1}^h {\varphi ^{g^{3k + 2} } } + \sum\limits_{k = 1}^h {\varphi ^{g^{3k} } } + \varepsilon \sum\limits_{k = 1}^h {\varphi ^{g^{3k + 1} } } } \right) = \varepsilon \eta _{\left( P \right)}
\]$")
Далее
![$\[
\left( {\eta _{\left( P \right)} ^{\left( {t_0 } \right)} } \right)^3 = \left( {\varepsilon \eta _{\left( P \right)} } \right)^3 = \eta _{\left( P \right)} ^3
\]$](https://dxdy-01.korotkov.co.uk/f/8/4/e/84e3ddd0d5eb97edcbd25c89cea8a5f782.png "$\[
\left( {\eta _{\left( P \right)} ^{\left( {t_0 } \right)} } \right)^3 = \left( {\varepsilon \eta _{\left( P \right)} } \right)^3 = \eta _{\left( P \right)} ^3
\]$")
Таким образом, все изоморфизмы
![$\[\eta _{\left( P \right)} ^3 \]$](https://dxdy-02.korotkov.co.uk/f/1/2/e/12ef607e95ce140e52286f2b1f9824e482.png "$\[\eta _{\left( P \right)} ^3 \]$")
оказались равны. А это возможно если
есть постоянная величина.
![$\eta_{(P)}^3 \in \mathbb{Z}[\varepsilon]$](https://dxdy-01.korotkov.co.uk/f/c/1/6/c167a18617a3c834cb39e42287b7388882.png "$\eta_{(P)}^3 \in \mathbb{Z}[\varepsilon]$")
, тоже совсем не очевидно.![$\[\eta _{\left( P \right)}\]$](https://dxdy-01.korotkov.co.uk/f/0/4/c/04cde655cadb32aa2abb67b20424765482.png "$\[\eta _{\left( P \right)}\]$")
![$\[
\eta _{\left( P \right)} ^{\left( t \right)} = \varsigma _1 ^{\left( t \right)} \left( {e^{\frac{{2\pi l}}{P}g^{3k} t} } \right) + \varepsilon \varsigma _2 ^{\left( t \right)} \left( {e^{\frac{{2\pi l}}{P}g^{3k + 1} t} } \right) + \varepsilon ^2 \varsigma _3 ^{\left( t \right)} \left( {e^{\frac{{2\pi l}}{P}g^{3k + 2} t} } \right)
\]$](https://dxdy-02.korotkov.co.uk/f/d/9/f/d9f1bd83c320c9e4c3e056095cd1e87f82.png "$\[
\eta _{\left( P \right)} ^{\left( t \right)} = \varsigma _1 ^{\left( t \right)} \left( {e^{\frac{{2\pi l}}{P}g^{3k} t} } \right) + \varepsilon \varsigma _2 ^{\left( t \right)} \left( {e^{\frac{{2\pi l}}{P}g^{3k + 1} t} } \right) + \varepsilon ^2 \varsigma _3 ^{\left( t \right)} \left( {e^{\frac{{2\pi l}}{P}g^{3k + 2} t} } \right)
\]$")
![$\[t = 1,...,P - 1\]$](https://dxdy-03.korotkov.co.uk/f/e/d/2/ed2ab2dbe3f09daf8717c617c554b98182.png "$\[t = 1,...,P - 1\]$")
получим ![$\[P - 1\]$](https://dxdy-01.korotkov.co.uk/f/4/5/2/45255d15886068b6d1a66e8ce529ccd482.png "$\[P - 1\]$")
различных изоморфизмов.
может принадлежать одному из трёх видов ![$\[g^{3a} ,g^{3a + 1} ,g^{3a + 2}\]$](https://dxdy-03.korotkov.co.uk/f/6/b/1/6b15ef1cc6967a031d16ab16dd4fe2b082.png "$\[g^{3a} ,g^{3a + 1} ,g^{3a + 2}\]$")
![$\[\varsigma \]$](https://dxdy-01.korotkov.co.uk/f/8/f/2/8f2b267dc74f946fc981ad46ad4a3c5d82.png "$\[\varsigma \]$")
на своих местах, второй сдвигает их вправо по кругу, третий - влево по кругу.![$\[\varepsilon ^2 ,\varepsilon \]$](https://dxdy-02.korotkov.co.uk/f/9/3/7/937cd596835d747c6e39047f0921c96382.png "$\[\varepsilon ^2 ,\varepsilon \]$")
и снова все ![$\[\eta _{\left( P \right)} ^3\]$](https://dxdy-01.korotkov.co.uk/f/c/0/1/c0192107e15c6ddc150cc68a4afa444e82.png "$\[\eta _{\left( P \right)} ^3\]$")
постоянное число.![$\[
\eta _{\left( P \right)} ^3 = P\left( {a + b\varepsilon } \right)
\]$](https://dxdy-04.korotkov.co.uk/f/7/0/6/7063d1051851e8ec4cb5be3fe439dfab82.png "$\[
\eta _{\left( P \right)} ^3 = P\left( {a + b\varepsilon } \right)
\]$")
![$\[\eta _{\left( P \right)} ^3 = m + n\varepsilon\]$](https://dxdy-04.korotkov.co.uk/f/f/2/0/f20c79b8a7985868ce3786b18545109282.png "$\[\eta _{\left( P \right)} ^3 = m + n\varepsilon\]$")
, ![$\[m,n\]$](https://dxdy-02.korotkov.co.uk/f/5/c/f/5cfe6216ef9d87d3b428748bcfdf71e482.png "$\[m,n\]$")
целые ![${\mathbb Q}(\[{e^{\frac{{2\pi l}}{P}} }\])$](https://dxdy-04.korotkov.co.uk/f/3/1/a/31ab211c288b20f7805869ecf07fe6eb82.png "${\mathbb Q}(\[{e^{\frac{{2\pi l}}{P}} }\])$")
![$\[
P = \delta \left( {1 - e^{\frac{{2\pi l}}{P}} } \right)^{P - 1}
\]$](https://dxdy-01.korotkov.co.uk/f/8/9/d/89d88c590c2f25eeb3de164650ee0cb082.png "$\[
P = \delta \left( {1 - e^{\frac{{2\pi l}}{P}} } \right)^{P - 1}
\]$")
![$\[\delta \]$](https://dxdy-01.korotkov.co.uk/f/8/9/7/897db2f9a92bccdf9d8d7970b7ee090482.png "$\[\delta \]$")
единица этого кольца.![$\[
\eta _{\left( P \right)} ^3 \equiv 0\left( {\bmod \left( {1 - e^{\frac{{2\pi l}}{P}} } \right)} \right)
\]$](https://dxdy-04.korotkov.co.uk/f/7/0/7/707cb6e9d129a8b5223375d04fd76e6182.png "$\[
\eta _{\left( P \right)} ^3 \equiv 0\left( {\bmod \left( {1 - e^{\frac{{2\pi l}}{P}} } \right)} \right)
\]$")
![$\[
\begin{array}{l}
\eta _{\left( P \right)} = \sum\limits_{k = 1}^h {\varphi ^{g^{3k} } } + \varepsilon \sum\limits_{k = 1}^h {\varphi ^{g^{3k + 1} } } + \varepsilon ^2 \sum\limits_{k = 1}^h {\varphi ^{g^{3k + 2} } } \equiv \sum\limits_{k = 1}^h 1 + \varepsilon \sum\limits_{k = 1}^h 1 + \varepsilon ^2 \sum\limits_{k = 1}^h 1 \equiv \\
h\left( {1 + \varepsilon + \varepsilon ^2 } \right) \equiv 0\left( {\bmod \left( {1 - e^{\frac{{2\pi l}}{P}} } \right)} \right) \\
\end{array}
\]$](https://dxdy-04.korotkov.co.uk/f/3/5/3/353b4163239b0bfc5d34cd2498391c7582.png "$\[
\begin{array}{l}
\eta _{\left( P \right)} = \sum\limits_{k = 1}^h {\varphi ^{g^{3k} } } + \varepsilon \sum\limits_{k = 1}^h {\varphi ^{g^{3k + 1} } } + \varepsilon ^2 \sum\limits_{k = 1}^h {\varphi ^{g^{3k + 2} } } \equiv \sum\limits_{k = 1}^h 1 + \varepsilon \sum\limits_{k = 1}^h 1 + \varepsilon ^2 \sum\limits_{k = 1}^h 1 \equiv \\
h\left( {1 + \varepsilon + \varepsilon ^2 } \right) \equiv 0\left( {\bmod \left( {1 - e^{\frac{{2\pi l}}{P}} } \right)} \right) \\
\end{array}
\]$")
![$\[
m + n\varepsilon = \eta _{\left( P \right)} ^3 \equiv 0\left( {\bmod \left( {1 - e^{\frac{{2\pi l}}{P}} } \right)} \right)
\]$](https://dxdy-02.korotkov.co.uk/f/5/c/f/5cfa04a1f62846738dc1622f7a00574882.png "$\[
m + n\varepsilon = \eta _{\left( P \right)} ^3 \equiv 0\left( {\bmod \left( {1 - e^{\frac{{2\pi l}}{P}} } \right)} \right)
\]$")
делятся на 
![$\[
\left( {a + b\varepsilon } \right)\left( {a + b\varepsilon ^2 } \right) = P
\]$](https://dxdy-04.korotkov.co.uk/f/7/b/b/7bbaa195c682d772bd480796d94901f382.png "$\[
\left( {a + b\varepsilon } \right)\left( {a + b\varepsilon ^2 } \right) = P
\]$")
![$\[
\eta _{\left( P \right)} \eta _{\left( P \right)} ' = \left( {\varsigma _1 + \varepsilon \varsigma _2 + \varepsilon ^2 \varsigma _3 } \right)\left( {\varsigma _1 + \varepsilon ^2 \varsigma _2 + \varepsilon \varsigma _3 } \right) = P
\]$](https://dxdy-02.korotkov.co.uk/f/9/f/3/9f3dce65d2445c652712e31d6e64445a82.png "$\[
\eta _{\left( P \right)} \eta _{\left( P \right)} ' = \left( {\varsigma _1 + \varepsilon \varsigma _2 + \varepsilon ^2 \varsigma _3 } \right)\left( {\varsigma _1 + \varepsilon ^2 \varsigma _2 + \varepsilon \varsigma _3 } \right) = P
\]$")
![$\[
\left( {\eta _{\left( P \right)} \eta _{\left( P \right)} '} \right)^3 = \left( {\eta _{\left( P \right)} } \right)^3 \left( {\eta _{\left( P \right)} '} \right)^3 = \left( {P\left( {a + b\varepsilon } \right)} \right)\left( {P\left( {a + b\varepsilon ^2 } \right)} \right) = P^3
\]$](https://dxdy-03.korotkov.co.uk/f/2/0/7/2074808522e684d22b35ee67cbbeea3082.png "$\[
\left( {\eta _{\left( P \right)} \eta _{\left( P \right)} '} \right)^3 = \left( {\eta _{\left( P \right)} } \right)^3 \left( {\eta _{\left( P \right)} '} \right)^3 = \left( {P\left( {a + b\varepsilon } \right)} \right)\left( {P\left( {a + b\varepsilon ^2 } \right)} \right) = P^3
\]$")
примарное.![$\[P \equiv 1\bmod 3\]$](https://dxdy-04.korotkov.co.uk/f/7/c/9/7c99ec775b393b91af1b85d3fd47342782.png "$\[P \equiv 1\bmod 3\]$")
![$\[
3 = \left( {1 - \varepsilon } \right)\left( {1 - \varepsilon ^2 } \right)
\]$](https://dxdy-02.korotkov.co.uk/f/5/6/3/563d97cf35d4f1a1193d0d2c3ebeba5a82.png "$\[
3 = \left( {1 - \varepsilon } \right)\left( {1 - \varepsilon ^2 } \right)
\]$")
![$\[\left( {1 - \varepsilon } \right)\]$](https://dxdy-03.korotkov.co.uk/f/a/4/7/a475160f6ae0b476e0d5d0e5962cd5d582.png "$\[\left( {1 - \varepsilon } \right)\]$")
![$\[
\eta _{\left( P \right)} = \varsigma _1 + \varsigma _2 \varepsilon + \varsigma _3 \varepsilon ^2 \equiv \varsigma _1 + \varsigma _2 + \varsigma _3 = - 1\left( {\bmod \left( {1 - \varepsilon } \right)} \right)
\]$](https://dxdy-03.korotkov.co.uk/f/a/9/e/a9ea2c6d20516257874b655a79aff84582.png "$\[
\eta _{\left( P \right)} = \varsigma _1 + \varsigma _2 \varepsilon + \varsigma _3 \varepsilon ^2 \equiv \varsigma _1 + \varsigma _2 + \varsigma _3 = - 1\left( {\bmod \left( {1 - \varepsilon } \right)} \right)
\]$")
![$\[
\eta _{\left( P \right)} ^3 = \left( {\varsigma _1 + \varsigma _2 \varepsilon + \varsigma _3 \varepsilon ^2 } \right)^3 \equiv \left( { - 1} \right)^3 \equiv 2 \equiv a + b\varepsilon \left( {\bmod \left( {1 - \varepsilon } \right)} \right)
\]$](https://dxdy-01.korotkov.co.uk/f/8/7/6/8766d5edee0255804362eee168426e1d82.png "$\[
\eta _{\left( P \right)} ^3 = \left( {\varsigma _1 + \varsigma _2 \varepsilon + \varsigma _3 \varepsilon ^2 } \right)^3 \equiv \left( { - 1} \right)^3 \equiv 2 \equiv a + b\varepsilon \left( {\bmod \left( {1 - \varepsilon } \right)} \right)
\]$")
![$\[a + b\varepsilon\]$](https://dxdy-04.korotkov.co.uk/f/b/1/f/b1f6d274cff344f6deeaa2f96dd1235282.png "$\[a + b\varepsilon\]$")
примарное.![$\[\alpha = m + n\varepsilon \]$](https://dxdy-03.korotkov.co.uk/f/2/6/a/26a521cefdca149097d748fc01443d2082.png "$\[\alpha = m + n\varepsilon \]$")
существует такое единственное целое число 
, что ![$\[\varepsilon ^k \alpha\]$](https://dxdy-01.korotkov.co.uk/f/c/5/e/c5e21fde17a147aaab12120070a2b7d582.png "$\[\varepsilon ^k \alpha\]$")
примарное.![$\[\varepsilon ^k \]$](https://dxdy-02.korotkov.co.uk/f/1/8/5/185e8c9e1363db7242c800e60327b45382.png "$\[\varepsilon ^k \]$")
, где ![$\[\varepsilon ^{3n} = 1\]$](https://dxdy-02.korotkov.co.uk/f/5/3/c/53c05b6c47c0524a749db57ebde05acd82.png "$\[\varepsilon ^{3n} = 1\]$")
![$\[
P = \left( {a + b\varepsilon } \right)\left( {a + b\varepsilon ^2 } \right)
\]$](https://dxdy-04.korotkov.co.uk/f/f/f/3/ff3e04bad1b5783f1b6423bdbaa424a082.png "$\[
P = \left( {a + b\varepsilon } \right)\left( {a + b\varepsilon ^2 } \right)
\]$")
![$\[
\left( {m + n\varepsilon } \right)\left( {m + n\varepsilon ^2 } \right) = P^3 c
\]$](https://dxdy-04.korotkov.co.uk/f/7/8/d/78d2b8d4d7bf677403e9022f2c9b83e582.png "$\[
\left( {m + n\varepsilon } \right)\left( {m + n\varepsilon ^2 } \right) = P^3 c
\]$")
![$\[m,n,c\]$](https://dxdy-01.korotkov.co.uk/f/0/f/8/0f8d30a95fa9af68ec64ea1df45fac9982.png "$\[m,n,c\]$")
целые.![$\[{m + n\varepsilon }\]$](https://dxdy-01.korotkov.co.uk/f/8/c/8/8c81ca128f753519c989f60e00b8b8e982.png "$\[{m + n\varepsilon }\]$")
![$\[P\left( {a + b\varepsilon } \right)\]$](https://dxdy-02.korotkov.co.uk/f/d/0/9/d09ebd10ae6d1a2db876224b165310ac82.png "$\[P\left( {a + b\varepsilon } \right)\]$")
, либо на ![$\[\left( {a + b\varepsilon } \right)^3\]$](https://dxdy-03.korotkov.co.uk/f/a/d/a/ada7aa8437244bfa31d2fbaa8623c4c682.png "$\[\left( {a + b\varepsilon } \right)^3\]$")
![$\[x^3 + px + q = 0,D = - 4p^3 - 27q^2 = d^2 \]$](https://dxdy-02.korotkov.co.uk/f/1/b/0/1b0e5c892c6342802cb1db16126c213e82.png "$\[x^3 + px + q = 0,D = - 4p^3 - 27q^2 = d^2 \]$")
![$\[
x = \sqrt[3]{{ - \frac{q}{2} + \sqrt {\left( {\frac{q}{2}} \right)^2 + \left( {\frac{p}{3}} \right)^3 } }} + \sqrt[3]{{ - \frac{q}{2} - \sqrt {\left( {\frac{q}{2}} \right)^2 + \left( {\frac{p}{3}} \right)^3 } }} =
\]$](https://dxdy-04.korotkov.co.uk/f/7/5/3/75323ae9ceb89a14523f12edf358a69582.png "$\[
x = \sqrt[3]{{ - \frac{q}{2} + \sqrt {\left( {\frac{q}{2}} \right)^2 + \left( {\frac{p}{3}} \right)^3 } }} + \sqrt[3]{{ - \frac{q}{2} - \sqrt {\left( {\frac{q}{2}} \right)^2 + \left( {\frac{p}{3}} \right)^3 } }} =
\]$")
![$\[
\sqrt[3]{{ - \frac{q}{2} + \frac{{\sqrt { - 3D} }}{{2 \cdot 3^2 }}}} + \sqrt[3]{{ - \frac{q}{2} - \frac{{\sqrt { - 3D} }}{{2 \cdot 3^2 }}}} =
\]$](https://dxdy-01.korotkov.co.uk/f/c/3/4/c341be1964a93fd18d168b6a3aef897b82.png "$\[
\sqrt[3]{{ - \frac{q}{2} + \frac{{\sqrt { - 3D} }}{{2 \cdot 3^2 }}}} + \sqrt[3]{{ - \frac{q}{2} - \frac{{\sqrt { - 3D} }}{{2 \cdot 3^2 }}}} =
\]$")
![$\[
\sqrt[3]{{\frac{{ - 9q + d\sqrt { - 3} }}{{2 \cdot 3^2 }}}} + \sqrt[3]{{\frac{{ - 9q - d\sqrt { - 3} }}{{2 \cdot 3^2 }}}} =
\]$](https://dxdy-01.korotkov.co.uk/f/0/0/b/00b1cb7407b2ea5f48518e1207af0cd182.png "$\[
\sqrt[3]{{\frac{{ - 9q + d\sqrt { - 3} }}{{2 \cdot 3^2 }}}} + \sqrt[3]{{\frac{{ - 9q - d\sqrt { - 3} }}{{2 \cdot 3^2 }}}} =
\]$")
![$\[
\frac{1}{{\sqrt[3]{{2 \cdot 9}}}}\left( {\sqrt[3]{{ - 9q + d\left( {2\varepsilon + 1} \right)}} + \sqrt[3]{{ - 9q + d\left( {2\varepsilon ^2 + 1} \right)}}} \right)
\]$](https://dxdy-03.korotkov.co.uk/f/6/5/6/65670a6457f20f0cf9b343058e835fa282.png "$\[
\frac{1}{{\sqrt[3]{{2 \cdot 9}}}}\left( {\sqrt[3]{{ - 9q + d\left( {2\varepsilon + 1} \right)}} + \sqrt[3]{{ - 9q + d\left( {2\varepsilon ^2 + 1} \right)}}} \right)
\]$")
![$\[
x = \frac{{\sqrt[3]{{\left( {d - 9q} \right) + 2d\varepsilon }} + \sqrt[3]{{\left( {d - 9q} \right) + 2d\varepsilon ^2 }}}}{{\sqrt[3]{{18}}}}
\]$](https://dxdy-01.korotkov.co.uk/f/c/3/e/c3e272e7ca43881d43ef79294294e99e82.png "$\[
x = \frac{{\sqrt[3]{{\left( {d - 9q} \right) + 2d\varepsilon }} + \sqrt[3]{{\left( {d - 9q} \right) + 2d\varepsilon ^2 }}}}{{\sqrt[3]{{18}}}}
\]$")
![${\mathbb Q}\[\left( {e^{\frac{{2\pi l}}{3}} } \right)\]$](https://dxdy-01.korotkov.co.uk/f/0/a/0/0a027fea7544bbee7d45da7e5310c9da82.png "${\mathbb Q}\[\left( {e^{\frac{{2\pi l}}{3}} } \right)\]$")
.![$\[
\varepsilon ,\varepsilon ^2 \]$](https://dxdy-03.korotkov.co.uk/f/a/d/7/ad7b9e4d8279a94e6a9c0b17fbede32482.png "$\[
\varepsilon ,\varepsilon ^2 \]$")
![$\[
\left( {d - 9q} \right) + 2d\varepsilon = \varepsilon ^k \prod\limits_{i = 1}^h {\left( {a_i + b_i \varepsilon } \right)}
\]$](https://dxdy-01.korotkov.co.uk/f/0/2/a/02a78754d2523e645cc3f55b9aa3b94582.png "$\[
\left( {d - 9q} \right) + 2d\varepsilon = \varepsilon ^k \prod\limits_{i = 1}^h {\left( {a_i + b_i \varepsilon } \right)}
\]$")
![$\[
a_i + b_i \varepsilon = \frac{{\eta _{\left( {P_i } \right)} ^3 }}{{P_i }}
\]$](https://dxdy-01.korotkov.co.uk/f/c/a/8/ca884a2feac22a267f02b21063809c5382.png "$\[
a_i + b_i \varepsilon = \frac{{\eta _{\left( {P_i } \right)} ^3 }}{{P_i }}
\]$")
![$\[
\left( {d - 9q} \right) + 2d\varepsilon = \varepsilon ^k \prod\limits_{i = 1}^h {\frac{{\eta _{\left( {P_i } \right)} ^3 }}{{P_i }}}
\]$](https://dxdy-01.korotkov.co.uk/f/c/f/b/cfb9bd09f84e6c15605ca641831690bf82.png "$\[
\left( {d - 9q} \right) + 2d\varepsilon = \varepsilon ^k \prod\limits_{i = 1}^h {\frac{{\eta _{\left( {P_i } \right)} ^3 }}{{P_i }}}
\]$")
![$\[
\left( {d - 9q} \right) + 2d\varepsilon ^2 = \varepsilon ^{2k} \prod\limits_{i = 1}^h {\frac{{\eta '_{\left( {P_i } \right)} ^3 }}{{P_i }}}
\]$](https://dxdy-04.korotkov.co.uk/f/f/d/7/fd71aac2f871b7cd6c94000ab6d54cac82.png "$\[
\left( {d - 9q} \right) + 2d\varepsilon ^2 = \varepsilon ^{2k} \prod\limits_{i = 1}^h {\frac{{\eta '_{\left( {P_i } \right)} ^3 }}{{P_i }}}
\]$")
![$\[\eta '_{\left( {P_i } \right)}\]$](https://dxdy-04.korotkov.co.uk/f/7/a/0/7a04dbbad9437c4abac91794baaa5a5282.png "$\[\eta '_{\left( {P_i } \right)}\]$")
сопряжённое ![$\[\eta_{\left( {P_i } \right)}\]$](https://dxdy-01.korotkov.co.uk/f/4/e/9/4e92bc2e05b47e62395b3ad43b2d799182.png "$\[\eta_{\left( {P_i } \right)}\]$")
![$\[
x = \frac{{\sqrt[3]{{\varepsilon ^k }}\prod\limits_{i = 1}^h {\eta _{\left( {P_i } \right)} } + \sqrt[3]{{\varepsilon ^{2k} }}\prod\limits_{i = 1}^h {\eta '_{\left( {P_i } \right)} } }}{{\sqrt[3]{{18\prod\limits_{i = 1}^h {P_i } }}}}
\]$](https://dxdy-03.korotkov.co.uk/f/2/f/e/2fe6d0531fa0aadc168cb9fed420aa3782.png "$\[
x = \frac{{\sqrt[3]{{\varepsilon ^k }}\prod\limits_{i = 1}^h {\eta _{\left( {P_i } \right)} } + \sqrt[3]{{\varepsilon ^{2k} }}\prod\limits_{i = 1}^h {\eta '_{\left( {P_i } \right)} } }}{{\sqrt[3]{{18\prod\limits_{i = 1}^h {P_i } }}}}
\]$")
![$\[
\left( {\left( {d - 9q} \right) + 2d\varepsilon } \right)\left( {\left( {d - 9q} \right) + 2d\varepsilon ^2 } \right) = - 12p^3
\]$](https://dxdy-03.korotkov.co.uk/f/2/e/f/2efedae0e9bc7ba7e0510bc5f505dde982.png "$\[
\left( {\left( {d - 9q} \right) + 2d\varepsilon } \right)\left( {\left( {d - 9q} \right) + 2d\varepsilon ^2 } \right) = - 12p^3
\]$")
, ![$\[
\prod\limits_{i = 1}^h {P_i } = c^3
\]$](https://dxdy-03.korotkov.co.uk/f/2/2/1/221221a8065546d688d69fe84355f86582.png "$\[
\prod\limits_{i = 1}^h {P_i } = c^3
\]$")
![$\[
\sqrt[3]{{\varepsilon ^k }} = e^{\frac{{2\pi kl}}{9}}\]$](https://dxdy-01.korotkov.co.uk/f/c/9/d/c9d32afc41ce11b07e68292e459673c282.png "$\[
\sqrt[3]{{\varepsilon ^k }} = e^{\frac{{2\pi kl}}{9}}\]$")
![$\[
x = \frac{1}{{c\sqrt[3]{{18}}}}\left( {e^{\frac{{2\pi kl}}{9}} \prod\limits_{i = 1}^h {\eta _{\left( {P_i } \right)} } + e^{\frac{{4\pi kl}}{9}} \prod\limits_{i = 1}^h {\eta '_{\left( {P_i } \right)} } } \right)
\]$](https://dxdy-02.korotkov.co.uk/f/d/3/5/d35c3212285f78414d2c5e4e91fb0d2d82.png "$\[
x = \frac{1}{{c\sqrt[3]{{18}}}}\left( {e^{\frac{{2\pi kl}}{9}} \prod\limits_{i = 1}^h {\eta _{\left( {P_i } \right)} } + e^{\frac{{4\pi kl}}{9}} \prod\limits_{i = 1}^h {\eta '_{\left( {P_i } \right)} } } \right)
\]$")