Questions tagged [complex-analysis]

For questions mainly about theory of complex analytic/holomorphic functions of one complex variable. Use [tag:complex-numbers] instead for questions about complex numbers. Use [tag:several-complex-variables] instead for questions about holomorphic functions of more than one complex variables.

Complex analysis is a branch of mathematical analysis that investigates functions of one or several complex variables. Typical topics include Cauchy's integral formula, singularities, poles, holomorphic and meromorphic functions, Laurent and Taylor series, maximum modulus principle, isolated zeros principle, etc.

Independent variable and dependent variable of complex functions are both complex numbers, and may be separated into real (denoted by $\Re$) and imaginary parts (denoted by $\Im$) : $z = x +iy$ and $w = f(z) =u(x,y)+iv(x,y)$ where $x, y \in \mathbb{R}$, $u(x,y)$ and $v(x,y)$ being real-valued functions.

A fundamental result of complex analysis is the Cauchy-Riemann equations, which give the conditions for a function to have a complex derivative, which is a complex generalization of the (real) derivative. If the complex derivative is defined at each point in an open connected subset of $\mathbb C$, the function is called analytic, or holomorphic. If the complex derivative is defined at each point in $\mathbb C$, the function is called entire.

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Determining transformation sending $|z|=2$ to $|z+1|=1$.

I'm trying to teach myself complex analysis, and am reading about linear fractional transformations. I want to find the transformation carrying the circle $|z|=2$ into $|z+1|=1$, $-2$ into the origin, and the origin into $i$. My text states that…
Dedede
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Show the level curves of $\log|f(z)|$ are orthogonal to those of $\operatorname{arg}(f(z))$.

Question: Suppose $f(z)$ is analytic in a neighbourhood where $f(z) \neq 0$. Show the level curves of $\log|f(z)|$ are orthogonal to those of $\operatorname{arg}(f(z))$. Here, I know I should use some of the angle preserving properties of…
mathjacks
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An entire function $f(z)$ is real iff $z$ is real

Let $f$ be an entire function s.t. $\forall z \in \mathbb{C}, f(z)\text{ is real}\iff z\text{ is real}$. Prove that $\exists a,b \in \mathbb{R}$ s.t. $a\neq 0$ and $\forall z \in \mathbb{C}, f(z)=az+b$. I think I have a proof for this using some…
user1537366
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a holomorphic function is uniform limit of polynomials

I was reviewing my complex analysis, and found this problem in a problem set. It says "prove that every holomorphic function on the disc $D=\{|z|<1\}$ is a uniform limit of polynomials". I'm confused about it, it seems to me that the statement as…
Franco
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On the Cayley (conformal) transform

Prove that the function $$ \begin{align} \phi (z) = i \dfrac{1 - z}{1 + z} \end{align} $$ maps the set $D = \{z \in \mathbb{C}: |z| < 1 \} $ one-to-one onto the set $U = \{ z \in \mathbb{C} : Im(z) > 0 \}$. (This is exercise 1.9 in "Function…
The Chaz 2.0
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Find all solutions of $e^z = e$ with $z \in \mathbb{C}$

How do we go about doing this? $e^z = e \implies e^{x+iy} = e \implies x+iy =1$ Obviously $(1,0)$ works, but what else?
logic
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$f^2$ holomorphic polynomial on the disc, $f$ entire, then $f$ is a polynomial.

I know this question will look similar to this link's question: https://math.stackexchange.com/questions/278397/f22f1-is-a-polynomial-implies-that-f-is-a-polynomial#= However, I am not entirely satisfied with either answer here. The first answer…
Johnny Apple
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Let $f:\mathbb C\to\mathbb C$ is entire function. And $f(z+1)=f(z)$ and $f(z+i)=f(z)$ then what can you say about $f$?

Let $f:\mathbb C\to\mathbb C$ is entire function. And $f(z+1)=f(z)$ and $f(z+i)=f(z)$ then what can you say about $f$ ? I guessed that it must be a constant because evaluating the function on a translation of $z$ by 1 unit and $i$ result the same.…
David
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Confusion about the Proof of Dieudonné's Criterion - Why doesn't it hold for analytic functions?

The following theorem is due to Dieudonné: Let $p(z) = a_0 + a_1 z + \cdots + a_n z^n$, a complex polynomial. $p$ is univalent on $D$, the unit disk, if and only if $f_\theta(z) = \sum_{k=1}^n a_k \dfrac{\sin(k\theta)}{\sin(\theta)} z^{k-1}$ has no…
Braindead
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Estimate on the derivative at fixed point

Let $D$ be a bounded domain and let $f$ be analytic function from $D$ into $D$. Show that if $z_{0}$ $\in D$ is a fixed point for $f$ , then $|f' (z_{0} )| \leq 1$. WHAT I WAS THINKING: To have a conformal mapping from $D$ to the unit disc & after…
user92360
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Fixed points of Holomorphic functions

Let $f:D(0,1) \to D(0,1)$ be a holomorphic map where $f$ has two distinct fixed points. Could anyone advise me how to prove $f$ is identity map? Do I use Schwarz-Pick somewhere? Let $g(z)=f(z)-z.$ Then $ |zg(z)|\leq \dfrac{a-z}{1-\overline{a}z},…
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The graph of $e^z$ for $|z|=1$

When $|z|=1$(unit circle in complex plane), what is the graph of $e^z$? I know that this transformation makes a band into a angle area, but I have no idea about this .
89085731
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For all $\xi \in \mathbb{C}$ we have $e^{-\pi\xi^2}=\int_{-\infty}^\infty \! e^{-\pi x^2}e^{2\pi ix\xi}\ \mathrm{d}x.$

This is Exercise 2.4 in Stein & Shakarchi's Complex Analysis. Prove that for all $\xi \in \mathbb{C}$ $$e^{-\pi\xi^2}=\int_{-\infty}^\infty \! e^{-\pi x^2}e^{2\pi ix\xi}\ \mathrm{d}x.$$ They prove it for the real case, so I assume that I'm supposed…
desi
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Using Cauchy's Integral Theorem to evaluate integral?

I'm going through Stein's Complex Analysis, and I'm a bit confused at one of the classical examples of using Cauchy's theorem to evaluate an integral. The example is: $$\int_0^{\infty}\frac{1-\cos{x}}{x^2}dx = \frac{\pi}{2}$$ The book says (and I'll…
r123454321
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Characterization of entire functions to be a polynomial

I need some help with this proposition: If $f:\mathbb{C}\longrightarrow \mathbb{C}$ is an entire function such that $\{z\in \mathbb{C}:f(z)=w\}$ is finite for all $w\in \mathrm{Im} (f)$ then $f$ is a polynomial. Any hint would be appreciated.
felipeuni
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