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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Transformation of $|z-1|=1$ and $\mathrm{Re}(z)^2 = \mathrm{Im }(z)^2-1$ under $f(z) = \sqrt{z}$

I have two regions in the complex plane, defined by $|z-1|=1$ and $(\,\mathrm{Im}(z))^2 = (\,\mathrm{Re}(z))^2-1$, $\mathrm{Re}(z)>0$. I am being asked to find and sketch the image of those regions under the mapping $f(z) = \sqrt{z}$ . My…
Santos
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Average value of a complex valued function on a circle.

The following is an exercise from Complex Analysis by Stephen Fisher. Fix a complex number $a$ and a positive real number $R$. Suppose $u$ is a function defined on the circle of radius $R$ centered at $a$. Let $C$ denote this circle. Show that the…
user24883
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Integrating $\int_0^\infty \frac{\ln x}{x^2+4}\,dx$ with residue theorem.

I want to calculate $$\int_0^\infty \frac{\ln x}{x^2+4}\,dx$$ using the Residue Theorem. The contour I want to use is almost the upper half circle of radius $R$, but going around $0$ following a half-circle of radius $\epsilon$, and using the…
user346096
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Show that $\frac{P(z)}{Q(z)} = \sum_{k=1}^{n}\frac{P(\alpha_k)}{Q'(\alpha_k)(z-\alpha_k)}$

Here, $Q$ is a polynomial with distinct roots $\alpha_1, \ldots, \alpha_n$ and $P$ is a polynomial of degree $
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Improper integral of $\sin^2(x)/x^2$ evaluated via residues

I have come across another improper integral I wish to evaluate via residues. The integral is: $$\int_{-\infty}^\infty{\frac{\sin(x)^2}{x^2}}dx$$ $\sin(z)$ behaves in an uneasy way so I tried using the function $\frac{{e^{iz}}^2}{z^2}$ with a half…
Mike
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How to prove $f(z)=|z|$ is nowhere differentiable

Hi so i am trying to prove that the function is not analytic but i am having trouble. I am supposed to use the definition $\frac{f(z+h)-f(z)}{h}$. I tried using the fact that $|z|=\sqrt{z\overline{z}}$ but I cannot see anything obvious. I know my…
Sorfosh
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A holomorphic function which has $|f(z)|>1$ for every $|z|=1$ and $|f(0)|<1$ has a fixed point inside the unit circle

Edit: the answer suggested by @ShakedBader posted here works for this question as well. But I'm curious about the extra assumption here about $|f(0)|$. Does it allow to solve the question using Rouche's lemma? Let $f$ be a holomorphic function on a…
mbrg
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Upper bound for zeros of holomorphic function

I'd appreciate some help with the following problem form Conway's book on functions of one complex variable: Let $f$ be analytic in $\overline B (0;R)$ with $|f(z)|\le M$ for $|z|\le R$ and $|f(0)|=a>0$. Show that the number of zeros of f in…
Sam
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holomorphic function on punctured disk satisfying $\left|f\left(\frac{1}{n}\right)\right|\leq\frac{1}{n!}$ has an essential singularity at $0$

Let $f$ be holomorphic non-constant on $D=\left\{ 0<\left|z\right|<10\right\}$ . Given that for all $n\in\mathbb{N}$: $\left|f\left(\frac{1}{n}\right)\right|\leq\frac{1}{n!}$ prove that $f$ has an essential singularity at $0$. Find an example of…
Nescio
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A holomorphic function $f$, injective on $\partial D$, must be injective in $\bar{D}$?

Prove: If $f$ is holomorphic on a neighborhood of the closed unit disc $\bar{D}$, and if $f$ is one-to-one on $\partial D$, then $f$ is one-to-one on $\bar{D}$. (Greene and Krantz's Function Theory of One Complex Variable (3rd), Ch. 5, Problem…
Teddy
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Holomorphic Function is Injective in a Neighborhood where it has Nonzero Derivative

Suppose $f : \Omega \to \mathbb{C}$ is a holomorphic function on some open set $\Omega.$ If $f'(z)\neq 0$ for some $z\in \Omega,$ does there necessarily exist a neighborhood $U$ of $z$ where $f$ is injective?
Naysh
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Entire function is polynomial of degree $n$ iff $z^{n}f(1/z) \to \alpha$ as $z \to 0$.

I am working through old qualifier questions in analysis over break, and I was hoping someone would be willing to help me verify (and correct) my proof for the following statement. I feel fairly confident in the forward side, but less so in the…
ml0105
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Find entire functions that satisfy certain conditions

1) Find all entire functions that are uniformly continuous on $\mathbb{C}$. 2) Find all entire functions $f(z)$ such that such that for every integer $n \geq 1$, $$\oint_{\partial\mathbb{D}} f(z)\bar{z}^ndz = 0,$$ where $\mathbb{D}$ is the unit…
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Find the residue of $f(z)$

Find the residue of $f(z)$ $$f(z) = \frac{z^{(1/4)}}{z+1}$$ So this is a pole of order 1 with a singularity at $z=-1$ $$z^{1/4}\Big|_{-1}\ = (-1)^{1/4}$$ And I'm not sure what to do with that. The book says the answer is $\frac{1+i}{\sqrt2}$
NMBL
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