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@@ -40,23 +40,21 @@ at $x$: For all $h \in k^{n}$: |
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\end{bem} |
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\begin{definition} |
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We set |
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\[ |
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\mathcal{I}(X)_x^{*} \coloneqq \{ P_x^{*} \colon P \in \mathcal{I}(X) \} |
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.\] |
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We set $\mathcal{I}(X)_x^{*}$ to be the ideal generated |
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by $P_x^{*}$ for all $P \in \mathcal{I}(X)$. |
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\end{definition} |
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\begin{satz} |
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The set $\mathcal{I}(X)_x^{*}$ is an ideal of $k[T_1, \ldots, T_n]$. |
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\end{satz} |
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\begin{proof} |
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By definition, $0 \in \mathcal{I}(X)_x^{*}$. Let $P_x^{*}, Q_x^{*}$ be elements |
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of $\mathcal{I}(X)_x^{*}$ coming from $P, Q \in \mathcal{I}(X)$. Then |
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$P_x^{*} - Q_x^{*}$ is of the form $R_x^{*}$ for some $R \in \mathcal{I}(X)$, where |
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$R = 0$, $R = P$, $R = Q$ or $R = P-Q$. Moreover, for $Q \in k[T_1, \ldots, T_n]$, |
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we have $P_x^{*} Q = (PQ)_x^{*} \in \mathcal{I}(X)_x^{*}$. |
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\end{proof} |
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%\begin{satz} |
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% The set $\mathcal{I}(X)_x^{*}$ is an ideal of $k[T_1, \ldots, T_n]$. |
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%\end{satz} |
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% |
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%\begin{proof} |
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% By definition, $0 \in \mathcal{I}(X)_x^{*}$. Let $P_x^{*}, Q_x^{*}$ be elements |
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% of $\mathcal{I}(X)_x^{*}$ coming from $P, Q \in \mathcal{I}(X)$. Then |
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% $P_x^{*} - Q_x^{*}$ is of the form $R_x^{*}$ for some $R \in \mathcal{I}(X)$, where |
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% $R = 0$, $R = P$, $R = Q$ or $R = P-Q$. Moreover, for $Q \in k[T_1, \ldots, T_n]$, |
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% we have $P_x^{*} Q = (PQ)_x^{*} \in \mathcal{I}(X)_x^{*}$. |
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%\end{proof} |
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\begin{bem}[] |
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The ideal $\mathcal{I}(X)^{*}$ is finitely generated. However, |
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@@ -324,29 +322,29 @@ consider the Zariski tangent space to $X$ at a point $x \in X$. |
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may vary with $x$. |
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\end{bem} |
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\begin{satz}[a Jacobian criterion] |
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If $(P_1, \ldots, P_m)$ are polynomials such that |
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$\mathcal{I}(X) = (P_1, \ldots, P_m)$ and $\operatorname{rk } P'(x) = m$, where |
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$P = (P_1, \ldots, P_m)$, then $x$ is a non-singular point of $X$. |
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\end{satz} |
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\begin{proof} |
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By \ref{kor:cone-in-tangent-space} and \ref{kor:tangent-kernel-jacobian} it suffices to show that |
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\[ |
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\mathcal{C}_x(X) \supseteq x + \bigcap_{i=1} ^{m} \text{ker } P_i'(x) |
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.\] By definition |
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\[ |
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\mathcal{C}_x(X) = x + \mathcal{V}_{k^{n}}(\mathcal{I}(X)_x^{*}) |
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\] and $\mathcal{I}(X)_x^{*} = \{ Q_x^{*} : Q \in \mathcal{I}(X)\} $. If $Q \in \mathcal{I}(X)$, |
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there exist polynomials $Q_1, \ldots, Q_m$ such that |
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$Q = \sum_{i=1}^{m} Q_i P_i$, so $Q_x^{*}$ is a linear combination of the $(P_i)_x^{*}$. |
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Since $\text{rk }(P_1'(x), \ldots, P_m'(x)) = m$, we have |
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$P_i'(x) \neq 0$ for all $i$. So $(P_i)_x^{*} = P_i'(x)$ in the Taylor expansion |
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of $P_i$ at $x$. So $Q_x^{*}$ is a linear combination |
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of $(P_1'(x), \ldots, P_m'(x))$, |
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which proves that if $h \in \bigcap_{i=1}^{m} \text{ker } P_i'(x)$, then |
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$Q_x^{*}(h) = 0$ for all $Q \in \mathcal{I}(X)$, hence |
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$x + h \in \mathcal{C}_x(X)$. |
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\end{proof} |
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%\begin{satz}[a Jacobian criterion] |
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% If $(P_1, \ldots, P_m)$ are polynomials such that |
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% $\mathcal{I}(X) = (P_1, \ldots, P_m)$ and $\operatorname{rk } P'(x) = m$, where |
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% $P = (P_1, \ldots, P_m)$, then $x$ is a non-singular point of $X$. |
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%\end{satz} |
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% |
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%\begin{proof} |
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% By \ref{kor:cone-in-tangent-space} and \ref{kor:tangent-kernel-jacobian} it suffices to show that |
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% \[ |
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% \mathcal{C}_x(X) \supseteq x + \bigcap_{i=1} ^{m} \text{ker } P_i'(x) |
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% .\] By definition |
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% \[ |
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% \mathcal{C}_x(X) = x + \mathcal{V}_{k^{n}}(\mathcal{I}(X)_x^{*}) |
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% \] and $\mathcal{I}(X)_x^{*} = \{ Q_x^{*} : Q \in \mathcal{I}(X)\} $. If $Q \in \mathcal{I}(X)$, |
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% there exist polynomials $Q_1, \ldots, Q_m$ such that |
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% $Q = \sum_{i=1}^{m} Q_i P_i$, so $Q_x^{*}$ is a linear combination of the $(P_i)_x^{*}$. |
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% Since $\text{rk }(P_1'(x), \ldots, P_m'(x)) = m$, we have |
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% $P_i'(x) \neq 0$ for all $i$. So $(P_i)_x^{*} = P_i'(x)$ in the Taylor expansion |
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% of $P_i$ at $x$. So $Q_x^{*}$ is a linear combination |
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% of $(P_1'(x), \ldots, P_m'(x))$, |
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% which proves that if $h \in \bigcap_{i=1}^{m} \text{ker } P_i'(x)$, then |
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% $Q_x^{*}(h) = 0$ for all $Q \in \mathcal{I}(X)$, hence |
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% $x + h \in \mathcal{C}_x(X)$. |
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%\end{proof} |
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\end{document} |
