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sharpe
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I have a question on the Schwartz-Christoffel formula.

The map is a conformal map from the unit disk to polygons. Let me give you a specific example. In fact, \begin{align*} \phi(z)=\int_{0}^z (1-u^n)^{-2/n}\,du \end{align*} maps $\mathbb{D}$ onto the interior of a regular polygon with $n$ sides.

We can know the modulus of continuity of general conformal maps. The following result is well known.

Let $\mathbb{D} \subset \mathbb{C}$ be the unit disk centered at the origin. A conformal map $f$ defined on $\mathbb{D}$ is $\alpha$-Hölder continuous ($\alpha \in (0,1]$) if and only if there exists $L \in (0,\infty)$ such that \begin{align*} |f'(z)| \le L(1-\|z\|^2)^{\alpha-1},\quad z \in \mathbb{D}, \end{align*} where we denote by $\|\cdot\|$ the Euclidean metric on $\mathbb{C}$.

According to this result, $\phi$ defined above is $(1-2/n)$-Hölder continuous. HoweverThat is, there exists $C>0$ such that \begin{equation} \| \phi(x)-\phi(y)\| \le C\|x-y\|^{1-2/n} \end{equation} for any $x,y \in \mathbb{D}$. However, I do not know the Hölder continuity of $\phi^{-1}$. I think that the index should be bigger than $1-2/n$. Can we show this? What is the specific and optimal index?

I have a question on the Schwartz-Christoffel formula.

The map is a conformal map from the unit disk to polygons. Let me give you a specific example. In fact, \begin{align*} \phi(z)=\int_{0}^z (1-u^n)^{-2/n}\,du \end{align*} maps $\mathbb{D}$ onto the interior of a regular polygon with $n$ sides.

We can know the modulus of continuity of general conformal maps. The following result is well known.

Let $\mathbb{D} \subset \mathbb{C}$ be the unit disk centered at the origin. A conformal map $f$ defined on $\mathbb{D}$ is $\alpha$-Hölder continuous ($\alpha \in (0,1]$) if and only if there exists $L \in (0,\infty)$ such that \begin{align*} |f'(z)| \le L(1-\|z\|^2)^{\alpha-1},\quad z \in \mathbb{D}, \end{align*} where we denote by $\|\cdot\|$ the Euclidean metric on $\mathbb{C}$.

According to this result, $\phi$ defined above is $(1-2/n)$-Hölder continuous. However, I do not know the Hölder continuity of $\phi^{-1}$. I think that the index should be bigger than $1-2/n$. Can we show this? What is the specific and optimal index?

I have a question on the Schwartz-Christoffel formula.

The map is a conformal map from the unit disk to polygons. Let me give you a specific example. In fact, \begin{align*} \phi(z)=\int_{0}^z (1-u^n)^{-2/n}\,du \end{align*} maps $\mathbb{D}$ onto the interior of a regular polygon with $n$ sides.

We can know the modulus of continuity of general conformal maps. The following result is well known.

Let $\mathbb{D} \subset \mathbb{C}$ be the unit disk centered at the origin. A conformal map $f$ defined on $\mathbb{D}$ is $\alpha$-Hölder continuous ($\alpha \in (0,1]$) if and only if there exists $L \in (0,\infty)$ such that \begin{align*} |f'(z)| \le L(1-\|z\|^2)^{\alpha-1},\quad z \in \mathbb{D}, \end{align*} where we denote by $\|\cdot\|$ the Euclidean metric on $\mathbb{C}$.

According to this result, $\phi$ defined above is $(1-2/n)$-Hölder continuous. That is, there exists $C>0$ such that \begin{equation} \| \phi(x)-\phi(y)\| \le C\|x-y\|^{1-2/n} \end{equation} for any $x,y \in \mathbb{D}$. However, I do not know the Hölder continuity of $\phi^{-1}$. I think that the index should be bigger than $1-2/n$. Can we show this? What is the specific and optimal index?

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I have a question on the Schwartz-Christoffel formula.

The map is a conformal map from the unit disk to polygons. Let me give you a specific example. In fact, \begin{align*} \phi(z)=\int_{0}^z (1-z^n)^{-2/n}\,dz \end{align*}\begin{align*} \phi(z)=\int_{0}^z (1-u^n)^{-2/n}\,du \end{align*} maps $\mathbb{D}$ onto the interior of a regular polygon with $n$ sides.

We can know the modulus of continuity of general conformal maps. The following result is well known.

Let $\mathbb{D} \subset \mathbb{C}$ be the unit disk centered at the origin. A conformal map $f$ defined on $\mathbb{D}$ is $\alpha$-Hölder continuous ($\alpha \in (0,1]$) if and only if there exists $L \in (0,\infty)$ such that \begin{align*} |f'(z)| \le L(1-\|z\|^2)^{\alpha-1},\quad z \in \mathbb{D}, \end{align*} where we denote by $\|\cdot\|$ the Euclidean metric on $\mathbb{C}$.

According to this result, $\phi$ defined above is $(1-2/n)$-Hölder continuous. However, I do not know the Hölder continuity of $\phi^{-1}$. I think that the index should be bigger than $1-2/n$. Can we show this? What is the specific and optimal index?

I have a question on the Schwartz-Christoffel formula.

The map is a conformal map from the unit disk to polygons. Let me give you a specific example. In fact, \begin{align*} \phi(z)=\int_{0}^z (1-z^n)^{-2/n}\,dz \end{align*} maps $\mathbb{D}$ onto the interior of a regular polygon with $n$ sides.

We can know the modulus of continuity of general conformal maps. The following result is well known.

Let $\mathbb{D} \subset \mathbb{C}$ be the unit disk centered at the origin. A conformal map $f$ defined on $\mathbb{D}$ is $\alpha$-Hölder continuous ($\alpha \in (0,1]$) if and only if there exists $L \in (0,\infty)$ such that \begin{align*} |f'(z)| \le L(1-\|z\|^2)^{\alpha-1},\quad z \in \mathbb{D}, \end{align*} where we denote by $\|\cdot\|$ the Euclidean metric on $\mathbb{C}$.

According to this result, $\phi$ defined above is $(1-2/n)$-Hölder continuous. However, I do not know the Hölder continuity of $\phi^{-1}$. I think that the index should be bigger than $1-2/n$. Can we show this? What is the specific and optimal index?

I have a question on the Schwartz-Christoffel formula.

The map is a conformal map from the unit disk to polygons. Let me give you a specific example. In fact, \begin{align*} \phi(z)=\int_{0}^z (1-u^n)^{-2/n}\,du \end{align*} maps $\mathbb{D}$ onto the interior of a regular polygon with $n$ sides.

We can know the modulus of continuity of general conformal maps. The following result is well known.

Let $\mathbb{D} \subset \mathbb{C}$ be the unit disk centered at the origin. A conformal map $f$ defined on $\mathbb{D}$ is $\alpha$-Hölder continuous ($\alpha \in (0,1]$) if and only if there exists $L \in (0,\infty)$ such that \begin{align*} |f'(z)| \le L(1-\|z\|^2)^{\alpha-1},\quad z \in \mathbb{D}, \end{align*} where we denote by $\|\cdot\|$ the Euclidean metric on $\mathbb{C}$.

According to this result, $\phi$ defined above is $(1-2/n)$-Hölder continuous. However, I do not know the Hölder continuity of $\phi^{-1}$. I think that the index should be bigger than $1-2/n$. Can we show this? What is the specific and optimal index?

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Martin Sleziak
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Inverse of the Schwartz-ChristffelChristoffel map and the continuity

I have a question on the Schwartz-ChristffelChristoffel formula.

The map is a conformal map from the unit disk to polygons. Let me give you a specific example. In fact, \begin{align*} \phi(z)=\int_{0}^z (1-z^n)^{-2/n}\,dz \end{align*} maps $\mathbb{D}$ onto the interior of a regular polygon with $n$ sides.

We can know the modulus of continuity of general conformal maps. The following result is well known.

Let $\mathbb{D} \subset \mathbb{C}$ be the unit disk centered at the origin. A conformal map $f$ defined on $\mathbb{D}$ is $\alpha$-Hölder continuous ($\alpha \in (0,1]$) if and only if there exists $L \in (0,\infty)$ such that \begin{align*} |f'(z)| \le L(1-\|z\|^2)^{\alpha-1},\quad z \in \mathbb{D}, \end{align*} where we denote by $\|\cdot\|$ the Euclidean metric on $\mathbb{C}$.

According to this result, $\phi$ defined above is $(1-2/n)$-Hölder continuous. However, I do not know the Hölder continuity of $\phi^{-1}$. I think that the index should be bigger than $1-2/n$. Can we show this? What is the specific and optimal index?

Inverse of the Schwartz-Christffel map and the continuity

I have a question on the Schwartz-Christffel formula.

The map is a conformal map from the unit disk to polygons. Let me give you a specific example. In fact, \begin{align*} \phi(z)=\int_{0}^z (1-z^n)^{-2/n}\,dz \end{align*} maps $\mathbb{D}$ onto the interior of a regular polygon with $n$ sides.

We can know the modulus of continuity of general conformal maps. The following result is well known.

Let $\mathbb{D} \subset \mathbb{C}$ be the unit disk centered at the origin. A conformal map $f$ defined on $\mathbb{D}$ is $\alpha$-Hölder continuous ($\alpha \in (0,1]$) if and only if there exists $L \in (0,\infty)$ such that \begin{align*} |f'(z)| \le L(1-\|z\|^2)^{\alpha-1},\quad z \in \mathbb{D}, \end{align*} where we denote by $\|\cdot\|$ the Euclidean metric on $\mathbb{C}$.

According to this result, $\phi$ defined above is $(1-2/n)$-Hölder continuous. However, I do not know the Hölder continuity of $\phi^{-1}$. I think that the index should be bigger than $1-2/n$. Can we show this? What is the specific and optimal index?

Inverse of the Schwartz-Christoffel map and the continuity

I have a question on the Schwartz-Christoffel formula.

The map is a conformal map from the unit disk to polygons. Let me give you a specific example. In fact, \begin{align*} \phi(z)=\int_{0}^z (1-z^n)^{-2/n}\,dz \end{align*} maps $\mathbb{D}$ onto the interior of a regular polygon with $n$ sides.

We can know the modulus of continuity of general conformal maps. The following result is well known.

Let $\mathbb{D} \subset \mathbb{C}$ be the unit disk centered at the origin. A conformal map $f$ defined on $\mathbb{D}$ is $\alpha$-Hölder continuous ($\alpha \in (0,1]$) if and only if there exists $L \in (0,\infty)$ such that \begin{align*} |f'(z)| \le L(1-\|z\|^2)^{\alpha-1},\quad z \in \mathbb{D}, \end{align*} where we denote by $\|\cdot\|$ the Euclidean metric on $\mathbb{C}$.

According to this result, $\phi$ defined above is $(1-2/n)$-Hölder continuous. However, I do not know the Hölder continuity of $\phi^{-1}$. I think that the index should be bigger than $1-2/n$. Can we show this? What is the specific and optimal index?

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sharpe
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sharpe
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