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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If $f$ is entire and $e^f$ is constant $f$ is constant

What I am trying to prove is that if $f$ is entire and $e^f$ is constant $f$ is constant. This is my attempt but I just can't go forward to get anything meaningful. $$e^{f(z)}=c$$ where $c\in \mathbb{C}$ is a constant. Then the set of solutions for…
Heisenberg
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Finding number of zero of $z^{10}+10z+9$ in the unit disc.

I am trying to find the number of zero of the polynomial $f(z)=z^{10}+10z+9$ in the disc $D(0,1)$. So far I used Rouché's theorem with $g(z)=z^{10}$ to find that there are 10 zeroes in $D(0,2)$. However, as $-1$ is a zero of $f$ and is in $D(0,1)$,…
Luc M
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Prove that an analytic function, real-valued on radii $[0, 1)$ and $[0, e^{i\pi\sqrt 2})$, is constant on the open unit disk

Suppose $f$ is analytic in the open unit disc and real valued on the radii $[0, 1)$ and $[0, e^{i \pi \sqrt 2})$. Prove that $f$ is constant. I'm not sure how to solve this.
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Continuous function on the unit circle must be $c\bar{z}$

This is a homework problem, so hints or rough outlines are strongly preferred to a full solution. Problem. Let $C$ be the unit circle. Suppose the continuous function $f : C \rightarrow \mathbb{C}$ on the unit circle satisfies $|f(z)| \leq M$ and…
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Differentiable and analytic function

I have the following function and I am trying to find if it is analytic and differentiable. I use cauchy-riemann to prove it. $$ f(x) = x^2 -x+y+i(y^2-5y-x)$$ $$u(x,y) = x^2-x+y$$ $$v(x,y) = y^2-5y-x$$ $$u_x = 2x-1$$ $$u_y = 1$$ $$v_x= -1$$ $$v_y=…
primer
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Show that the integral of Riemann function is analytic

I'm trying to resolve this problem. Let $\Omega$ be an open set no empty of $\mathbb C$, $[a,b]$ a compact interval of $\mathbb{R}$, further $f,\ g\colon[a,b] \to \mathbb C$ two integrable Riemann functions. Suppose that $f(t) \notin \Omega$ for…
KTL
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Determining where a function is complex differentiable

I have a homework question, and I'm having a hard time interpreting it. Question: Where is the function $f(x+iy)=x^4y^5+ixy^3$ complex differentiable? Determine the derivative in such points. My first plan was to find a region for which the…
stats_qs
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Entire function f which satisfy $|f(z)| \leq |\exp(z)|$

Can someone confirm whether or not my solution to the following question is okay? Or if I'm missing something Question: Let f be an entire function satisfying: $|f(z)| \leq |\exp(z)| ,\: \forall z \in \mathbb{C}$. Show that there exist a $c \in…
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pole at infinity iff f is a polynomial

I need to show that if $f$ is an entire function it has a pole at infinity if and only if it is a polynomial. If I start with a polynomial, it is easy to show that it has a pole at infinity, but the other implication is harder. That is, I want to…
user119615
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Proof of Casorati-Weierstrass?

In Stein's Complex Analysis, he presents the following statement and proof of Casorati-Weierstrass: Suppose $f$ is holomorphic in the punctured disc $D_r(z_0) - \{z_0\}$ and has an essential singularity at $z_0$. Then, the image of $d_r(z_0) -…
r123454321
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Integrating Fresnel Integrals with Cauchy Theorem?

In regards to the above proof, I'm a little confused as to how the last conclusion was made -- How does the fact that $$\int_{-\infty}^{\infty}e^{-x^2}dx = \sqrt{\pi}$$ to conclude that: $$\int_0^{\infty}\cos{x^2} + i\sin{x^2}dx =…
r123454321
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If $f,g$ are entire functions and$\ fg\equiv 0$ then either $f \equiv 0$ or $g\equiv0. $

Let $f,g$ be entire functions such that $g \not\equiv 0.$ If $fg\equiv0$ in $\mathbb{C},$ could anyone advise me how to show $f \equiv0$ in $\mathbb{C} \ ?$ Thank you.
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Conformal map between $\mathbb{C}\setminus((-\infty, -1]\cup[1,\infty))$ and $\{z \in \mathbb{C} \mid 0 < \operatorname{Im}(z) < 7\}$

As it says in the title, I am looking for a conformal map from $\mathbb{C}\setminus((-\infty, -1]\cup[1,\infty))$ to $\{z \in \mathbb{C} \mid 0 < \operatorname{Im}(z) < 7\}$, but with the following restriction on the boundary components: $(-\infty,…
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Entire function such that $|f(z)| = 1$ on the real line

Let $f: \mathbb{C} \rightarrow \mathbb{C}$ be an entire function such that $|f(z)| = 1$ for all $z \in \mathbb{R}$. The problem is to show that $f$ does not vanish on $\mathbb{C}$. Here's my attempt: Note that $1/\overline{f(\overline{z})}$ is…
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Evaluation of Sum of $ \sum_{n=1}^{\infty}\frac{\sin (n)}{n}$.

If $\displaystyle S = \sum_{n=1}^{\infty}\frac{\sin (n)}{n}.$ Then value of $2S+1 = $ Using Fourier Series Transformation I am Getting $2S+1=\pi$ But I want to solve it Using Euler Method and Then Use Logarithmic Series. $\bf{My\; Try::}$ Using…
juantheron
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