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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Show that an entire function is a proper if and only if it is a nonconstant polynomial

Show that an entire function (Holomorphic on $ \mathbb C$) is proper if and only if it is a non constant polynomial. Def:A map $f:X\to Y$ is called proper if $f^{-1}(K)$ is compact for every compact set $K$ in $Y$. Clearly every non constant…
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let $f$ be holomorphic on the unit sphere and $|f(z)| = 1$ for $|z| = 1$ and $f(-1) = 1$. Furthermore $f$ has no zero's, determine $f$

let $f$ be holomorphic on the unit sphere and continous on the closure, suppose $|f(z)| = 1$ for $|z| = 1$ and $f(-1) = 1$. furthermore $f$ has no zero's, determine $f$. So far i know with the maximum-modulus theorem that $f(x)$ has a maximum at the…
user67149
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Show $f(z)$ can be analytically continued and $F(z+4)=F(z)$ for resulting entire function

I'm working on some past qualifying exam problems in complex analysis and I'm quite stuck on this one: Let $f(z)$ be analytic in $\{z\in\mathbb{C}\,:\,|\text{Re }z|<1\}$ and continuous on the closure of that domain. Suppose that $f(z)$ is real on…
Blake
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Prove $f(z)$ is a polynomial if $|f(z)| \leq (1 + |z|)^n$

Prove $f(z)$ is a polynomial if $f(z)$ is entire and $|f(z)| \leq (1 + |z|)^n$ $\forall z \in C$. Here is what I wrote for my proof: $f(z)$ can be represented as a power series $\sum\limits_{n=0}^\infty a_n z^n$ where $a_n = \frac{f^n(0)}{n!}$ if…
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If $f = u + iv$ is entire and $|u(z)| > |v(z)|$ for all $z$, is $f$ constant?

If $f = u + iv$ is entire and $|u(z)| > |v(z)|$ for all $z$, is $f$ constant? What's a good way to approach this problem? Maybe I want to use Liouville's theorem, so I need to show that $f(z)$ is bounded. However I don't see how to prove this from…
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Conditions for being harmonic in a region $R$

Prove that the function $G=\ln|f(z)|$ is harmonic in a region $R$ if $f(z)$ is analytic in $R$ and also $f(z)\cdot f'(z)$ does not equal zero in $R$. My difficulty here is that the expression for the Laplacian of $G$ is very big and ugly, and I…
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A Functional equation in Complex variables

I have been stuck on this problem for a long time : If $f(z)=u(x,y)+iv(x,y)$ , prove that a. $f(z)=2u(z/2,(-iz)/2) +$ constant b.$f(z)=2iv(z/2,(-iz)/2) +$ constant This result seems very interesting in itself ( nothing that I have done comes close…
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Rational function which is bijective on unit disk

What is the general form of a rational function which is bijective on the unit disk? I'm stuck on this problem. If I let $R(z) = \frac{a_0(z-a_n) \cdots (z-a_1)}{(z-b_m)\cdots (z-b_1)}$, then exactly one of the $a_i$ must fall in the unit disk and…
countunique
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Analytic functions and open mappings

Can someone explain why complex analytic functions should be open mappings. A complex analytic function $f:D \to \mathbb{C}$ on some open domain $D$ can be thought of as $f:D \to \mathbb{R}^2$, $f(x,y)= (f_1(x,y),f_2(x,y))$. The Cauchy Riemann…
user782220
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Showing $f(z)=x^2+iy^3$ is not analytic anywhere

I want to show that the following function is not analytic anywhere. $$f(z)=x^2+iy^3$$ Now I don't really understand the Cauchy-Riemann equations, but it seems we take: $$u(x,y)=x^2,v(x,y)=y^3$$ as we normally would, and take the partial…
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What's wrong in this equation? (Regarding Euler's eqn)

I got an idea, but that doesn't match with Euler's theory.. So What's wrong?! $$e^{jx} = (e^{j 2\pi})^{x/2\pi} = 1^{x/2\pi} = 1$$
DarkLight
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Cauchy inequality

This is supposed to be an upper bound counterpart for the Cauchy inequality. Let $f$ be entire and $M(R) = sup_{|z|=R} |f(z)|$ and $A(R) = sup _{n≥0} |a_n|R^n$ prove that $2A(2R)$ ≥ $M(R)$ I used Cauchy formula on circle $|z| =2r$ : …
Khoa
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Bounded analytic function on a punctured region

Let $G$ be a region in $\mathbb{C}$ and $a\in G$. Suppose $f:G-\{a\}\to\mathbb{C}$ is an injective analytic function such that $f(G-\{a\})=\Omega$ is bounded. Show that $f(a)\in\partial\Omega$. I know a couple things. Since $f$ is injective it's…
Bey
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How can one find the largest disk about $0$ such that $z^2+z$ is injective?

I'm trying to find the radius of the largest disk about the origin so that the map $f(z)=z^2+z$ is injective. I know $f(0)=0$ and $f'(0)=1\neq 0$, so there is at least some disk of positive radius where $f(z)$ is injective. Also, $f(0)=f(-1)=0$, so…
Dedede
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Prove that $\frac{1}{z+i} +\sin(z)=0$ has infinite solutions over $\mathbb{C}$

Prove that $\frac{1}{z+i} +\sin(z)=0$ has infinite solutions over $\mathbb{C}$ Can someone give me a clue?
UserB95
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