Paper 1, Section I, B

Complex Analysis or Complex Methods | Part IB, 2021

Let $x>0, x \neq 2$ , and let $C_{x}$ denote the positively oriented circle of radius $x$ centred at the origin. Define

g(x)=\oint_{C_{x}} \frac{z^{2}+e^{z}}{z^{2}(z-2)} d z

Evaluate $g(x)$ for $x \in(0, \infty) \backslash\{2\}$ .

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Paper 1, Section II, G

Complex Analysis or Complex Methods | Part IB, 2021

(a) State a theorem establishing Laurent series of analytic functions on suitable domains. Give a formula for the $n^{\text {th }}$ Laurent coefficient.

Define the notion of isolated singularity. State the classification of an isolated singularity in terms of Laurent coefficients.

Compute the Laurent series of

f(z)=\frac{1}{z(z-1)}

on the annuli $A_{1}=\{z: 0<|z|<1\}$ and $A_{2}=\{z: 1<|z|\}$ . Using this example, comment on the statement that Laurent coefficients are unique. Classify the singularity of $f$ at 0 .

(b) Let $U$ be an open subset of the complex plane, let $a \in U$ and let $U^{\prime}=U \backslash\{a\}$ . Assume that $f$ is an analytic function on $U^{\prime}$ with $|f(z)| \rightarrow \infty$ as $z \rightarrow a$ . By considering the Laurent series of $g(z)=\frac{1}{f(z)}$ at $a$ , classify the singularity of $f$ at $a$ in terms of the Laurent coefficients. [You may assume that a continuous function on $U$ that is analytic on $U^{\prime}$ is analytic on $U$ .]

Now let $f: \mathbb{C} \rightarrow \mathbb{C}$ be an entire function with $|f(z)| \rightarrow \infty$ as $z \rightarrow \infty$ . By considering Laurent series at 0 of $f(z)$ and of $h(z)=f\left(\frac{1}{z}\right)$ , show that $f$ is a polynomial.

(c) Classify, giving reasons, the singularity at the origin of each of the following functions and in each case compute the residue:

g(z)=\frac{\exp (z)-1}{z \log (z+1)} \quad \text { and } \quad h(z)=\sin (z) \sin (1 / z)

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Paper 2, Section II, B

Complex Analysis or Complex Methods | Part IB, 2021

(a) Let $f: \mathbb{C} \rightarrow \mathbb{C}$ be an entire function and let $a>0, b>0$ be constants. Show that if

|f(z)| \leqslant a|z|^{n / 2}+b

for all $z \in \mathbb{C}$ , where $n$ is a positive odd integer, then $f$ must be a polynomial with degree not exceeding $\lfloor n / 2\rfloor$ (closest integer part rounding down).

Does there exist a function $f$ , analytic in $\mathbb{C} \backslash\{0\}$ , such that $|f(z)| \geqslant 1 / \sqrt{|z|}$ for all nonzero $z ?$ Justify your answer.

(b) State Liouville's Theorem and use it to show the following.

(i) If $u$ is a positive harmonic function on $\mathbb{R}^{2}$ , then $u$ is a constant function.

(ii) Let $L=\{z \mid z=a x+b, x \in \mathbb{R}\}$ be a line in $\mathbb{C}$ where $a, b \in \mathbb{C}, a \neq 0$ . If $f: \mathbb{C} \rightarrow \mathbb{C}$ is an entire function such that $f(\mathbb{C}) \cap L=\emptyset$ , then $f$ is a constant function.

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Paper 1, Section I, G

Complex Analysis or Complex Methods | Part IB, 2020

Let $D$ be the open disc with centre $e^{2 \pi i / 6}$ and radius 1 , and let $L$ be the open lower half plane. Starting with a suitable Möbius map, find a conformal equivalence (or conformal bijection) of $D \cap L$ onto the open unit disc.

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Paper 1, Section II, G

Complex Analysis or Complex Methods | Part IB, 2020

Let $\ell(z)$ be an analytic branch of $\log z$ on a domain $D \subset \mathbb{C} \backslash\{0\}$ . Write down an analytic branch of $z^{1 / 2}$ on $D$ . Show that if $\psi_{1}(z)$ and $\psi_{2}(z)$ are two analytic branches of $z^{1 / 2}$ on $D$ , then either $\psi_{1}(z)=\psi_{2}(z)$ for all $z \in D$ or $\psi_{1}(z)=-\psi_{2}(z)$ for all $z \in D$ .

Describe the principal value or branch $\sigma_{1}(z)$ of $z^{1 / 2}$ on $D_{1}=\mathbb{C} \backslash\{x \in \mathbb{R}: x \leqslant 0\}$ . Describe a branch $\sigma_{2}(z)$ of $z^{1 / 2}$ on $D_{2}=\mathbb{C} \backslash\{x \in \mathbb{R}: x \geqslant 0\}$ .

Construct an analytic branch $\varphi(z)$ of $\sqrt{1-z^{2}}$ on $\mathbb{C} \backslash\{x \in \mathbb{R}:-1 \leqslant x \leqslant 1\}$ with $\varphi(2 i)=\sqrt{5}$ . [If you choose to use $\sigma_{1}$ and $\sigma_{2}$ in your construction, then you may assume without proof that they are analytic.]

Show that for $0<|z|<1$ we have $\varphi(1 / z)=-i \sigma_{1}\left(1-z^{2}\right) / z$ . Hence find the first three terms of the Laurent series of $\varphi(1 / z)$ about 0 .

Set $f(z)=\varphi(z) /\left(1+z^{2}\right)$ for $|z|>1$ and $g(z)=f(1 / z) / z^{2}$ for $0<|z|<1$ . Compute the residue of $g$ at 0 and use it to compute the integral

\int_{|z|=2} f(z) d z

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Paper 2, Section II, B

Complex Analysis or Complex Methods | Part IB, 2020

For the function

f(z)=\frac{1}{z(z-2)}

find the Laurent expansions

(i) about $z=0$ in the annulus $0<|z|<2$ ,

(ii) about $z=0$ in the annulus $2<|z|<\infty$ ,

(iii) about $z=1$ in the annulus $0<|z-1|<1$ .

What is the nature of the singularity of $f$ , if any, at $z=0, z=\infty$ and $z=1$ ?

Using an integral of $f$ , or otherwise, evaluate

\int_{0}^{2 \pi} \frac{2-\cos \theta}{5-4 \cos \theta} d \theta

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Paper 1, Section I, F

Complex Analysis or Complex Methods | Part IB, 2019

What is the Laurent series for a function $f$ defined in an annulus $A$ ? Find the Laurent series for $f(z)=\frac{10}{(z+2)\left(z^{2}+1\right)}$ on the annuli

\begin{aligned} &A_{1}=\{z \in \mathbb{C}|0<| z \mid<1\} \quad \text { and } \\ &A_{2}=\{z \in \mathbb{C}|1<| z \mid<2\} \end{aligned}

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Paper 1, Section II, F

Complex Analysis or Complex Methods | Part IB, 2019

State and prove Jordan's lemma.

What is the residue of a function $f$ at an isolated singularity $a$ ? If $f(z)=\frac{g(z)}{(z-a)^{k}}$ with $k$ a positive integer, $g$ analytic, and $g(a) \neq 0$ , derive a formula for the residue of $f$ at $a$ in terms of derivatives of $g$ .

Evaluate

\int_{-\infty}^{\infty} \frac{x^{3} \sin x}{\left(1+x^{2}\right)^{2}} d x

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Paper 2, Section II, D

Complex Analysis or Complex Methods | Part IB, 2019

Let $C_{1}$ and $C_{2}$ be smooth curves in the complex plane, intersecting at some point $p$ . Show that if the map $f: \mathbb{C} \rightarrow \mathbb{C}$ is complex differentiable, then it preserves the angle between $C_{1}$ and $C_{2}$ at $p$ , provided $f^{\prime}(p) \neq 0$ . Give an example that illustrates why the condition $f^{\prime}(p) \neq 0$ is important.

Show that $f(z)=z+1 / z$ is a one-to-one conformal map on each of the two regions $|z|>1$ and $0<|z|<1$ , and find the image of each region.

Hence construct a one-to-one conformal map from the unit disc to the complex plane with the intervals $(-\infty,-1 / 2]$ and $[1 / 2, \infty)$ removed.

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Paper 1, Section I, A

Complex Analysis or Complex Methods | Part IB, 2018

(a) Show that

w=\log (z)

is a conformal mapping from the right half $z$ -plane, $\operatorname{Re}(z)>0$ , to the strip

S=\left\{w:-\frac{\pi}{2}<\operatorname{Im}(w)<\frac{\pi}{2}\right\}

for a suitably chosen branch of $\log (z)$ that you should specify.

(b) Show that

w=\frac{z-1}{z+1}

is a conformal mapping from the right half $z$ -plane, $\operatorname{Re}(z)>0$ , to the unit disc

D=\{w:|w|<1\}

(c) Deduce a conformal mapping from the strip $S$ to the disc $D$ .

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Paper 1, Section II, A

Complex Analysis or Complex Methods | Part IB, 2018

(a) Let $C$ be a rectangular contour with vertices at $\pm R+\pi i$ and $\pm R-\pi i$ for some $R>0$ taken in the anticlockwise direction. By considering

\lim _{R \rightarrow \infty} \oint_{C} \frac{e^{i z^{2} / 4 \pi}}{e^{z / 2}-e^{-z / 2}} d z

show that

\lim _{R \rightarrow \infty} \int_{-R}^{R} e^{i x^{2} / 4 \pi} d x=2 \pi e^{\pi i / 4}

(b) By using a semi-circular contour in the upper half plane, calculate

\int_{0}^{\infty} \frac{x \sin (\pi x)}{x^{2}+a^{2}} d x

for $a>0$ .

[You may use Jordan's Lemma without proof.]

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Paper 2, Section II, A

Complex Analysis or Complex Methods | Part IB, 2018

(a) Let $f(z)$ be a complex function. Define the Laurent series of $f(z)$ about $z=z_{0}$ , and give suitable formulae in terms of integrals for calculating the coefficients of the series.

(b) Calculate, by any means, the first 3 terms in the Laurent series about $z=0$ for

f(z)=\frac{1}{e^{2 z}-1}

Indicate the range of values of $|z|$ for which your series is valid.

(c) Let

g(z)=\frac{1}{2 z}+\sum_{k=1}^{m} \frac{z}{z^{2}+\pi^{2} k^{2}}

Classify the singularities of $F(z)=f(z)-g(z)$ for $|z|<(m+1) \pi$ .

(d) By considering

\oint_{C_{R}} \frac{F(z)}{z^{2}} d z

where $C_{R}=\{|z|=R\}$ for some suitably chosen $R>0$ , show that

\sum_{k=1}^{\infty} \frac{1}{k^{2}}=\frac{\pi^{2}}{6}

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Paper 1, Section I, A

Complex Analysis or Complex Methods | Part IB, 2017

Let $F(z)=u(x, y)+i v(x, y)$ where $z=x+i y$ . Suppose $F(z)$ is an analytic function of $z$ in a domain $\mathcal{D}$ of the complex plane.

Derive the Cauchy-Riemann equations satisfied by $u$ and $v$ .

For $u=\frac{x}{x^{2}+y^{2}}$ find a suitable function $v$ and domain $\mathcal{D}$ such that $F=u+i v$ is analytic in $\mathcal{D}$ .

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Paper 1, Section II, A

Complex Analysis or Complex Methods | Part IB, 2017

(a) Let $f(z)$ be defined on the complex plane such that $z f(z) \rightarrow 0$ as $|z| \rightarrow \infty$ and $f(z)$ is analytic on an open set containing $\operatorname{Im}(z) \geqslant-c$ , where $c$ is a positive real constant.

Let $C_{1}$ be the horizontal contour running from $-\infty-i c$ to $+\infty-i c$ and let

F(\lambda)=\frac{1}{2 \pi i} \int_{C_{1}} \frac{f(z)}{z-\lambda} d z

By evaluating the integral, show that $F(\lambda)$ is analytic for $\operatorname{Im}(\lambda)>-c$ .

(b) Let $g(z)$ be defined on the complex plane such that $z g(z) \rightarrow 0$ as $|z| \rightarrow \infty$ with $\operatorname{Im}(z) \geqslant-c$ . Suppose $g(z)$ is analytic at all points except $z=\alpha_{+}$ and $z=\alpha_{-}$ which are simple poles with $\operatorname{Im}\left(\alpha_{+}\right)>c$ and $\operatorname{Im}\left(\alpha_{-}\right)<-c$ .

Let $C_{2}$ be the horizontal contour running from $-\infty+i c$ to $+\infty+i c$ , and let

\begin{gathered} H(\lambda)=\frac{1}{2 \pi i} \int_{C_{1}} \frac{g(z)}{z-\lambda} d z \\ J(\lambda)=-\frac{1}{2 \pi i} \int_{C_{2}} \frac{g(z)}{z-\lambda} d z . \end{gathered}

(i) Show that $H(\lambda)$ is analytic for $\operatorname{Im}(\lambda)>-c$ .

(ii) Show that $J(\lambda)$ is analytic for $\operatorname{Im}(\lambda)<c$ .

(iii) Show that if $-c<\operatorname{Im}(\lambda)<c$ then $H(\lambda)+J(\lambda)=g(\lambda)$ .

[You should be careful to make sure you consider all points in the required regions.]

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Paper 2, Section II, 13A

Complex Analysis or Complex Methods | Part IB, 2017

State the residue theorem.

By considering

\oint_{C} \frac{z^{1 / 2} \log z}{1+z^{2}} d z

with $C$ a suitably chosen contour in the upper half plane or otherwise, evaluate the real integrals

\int_{0}^{\infty} \frac{x^{1 / 2} \log x}{1+x^{2}} d x

and

\int_{0}^{\infty} \frac{x^{1 / 2}}{1+x^{2}} d x

where $x^{1 / 2}$ is taken to be the positive square root.

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Paper 1, Section I, A

Complex Analysis or Complex Methods | Part IB, 2016

Classify the singularities of the following functions at both $z=0$ and at the point at infinity on the extended complex plane:

\begin{aligned} f_{1}(z) &=\frac{e^{z}}{z \sin ^{2} z}, \\ f_{2}(z) &=\frac{1}{z^{2}(1-\cos z)}, \\ f_{3}(z) &=z^{2} \sin (1 / z) \end{aligned}

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Paper 1, Section II, A

Complex Analysis or Complex Methods | Part IB, 2016

Let $w=u+i v$ and let $z=x+i y$ , for $u, v, x, y$ real.

(a) Let A be the map defined by $w=\sqrt{z}$ , using the principal branch. Show that A maps the region to the left of the parabola $y^{2}=4(1-x)$ on the $z-$ plane, with the negative real axis $x \in(-\infty, 0]$ removed, into the vertical strip of the $w-$ plane between the lines $u=0$ and $u=1$ .

(b) Let $\mathrm{B}$ be the map defined by $w=\tan ^{2}(z / 2)$ . Show that $\mathrm{B}$ maps the vertical strip of the $z$ -plane between the lines $x=0$ and $x=\pi / 2$ into the region inside the unit circle on the $w$ -plane, with the part $u \in(-1,0]$ of the negative real axis removed.

(c) Using the results of parts (a) and (b), show that the map C, defined by $w=\tan ^{2}(\pi \sqrt{z} / 4)$ , maps the region to the left of the parabola $y^{2}=4(1-x)$ on the $z$ -plane, including the negative real axis, onto the unit disc on the $w$ -plane.

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Paper 2, Section II, A

Complex Analysis or Complex Methods | Part IB, 2016

Let $a=N+1 / 2$ for a positive integer $N$ . Let $C_{N}$ be the anticlockwise contour defined by the square with its four vertices at $a \pm i a$ and $-a \pm i a$ . Let

I_{N}=\oint_{C_{N}} \frac{d z}{z^{2} \sin (\pi z)}

Show that $1 / \sin (\pi z)$ is uniformly bounded on the contours $C_{N}$ as $N \rightarrow \infty$ , and hence that $I_{N} \rightarrow 0$ as $N \rightarrow \infty$ .

Using this result, establish that

\sum_{n=1}^{\infty} \frac{(-1)^{n-1}}{n^{2}}=\frac{\pi^{2}}{12}

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Paper 1, Section I, B

Complex Analysis or Complex Methods | Part IB, 2015

Consider the analytic (holomorphic) functions $f$ and $g$ on a nonempty domain $\Omega$ where $g$ is nowhere zero. Prove that if $|f(z)|=|g(z)|$ for all $z$ in $\Omega$ then there exists a real constant $\alpha$ such that $f(z)=e^{i \alpha} g(z)$ for all $z$ in $\Omega$ .

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Paper 1, Section II, B

Complex Analysis or Complex Methods | Part IB, 2015

(i) Show that transformations of the complex plane of the form

\zeta=\frac{a z+b}{c z+d}

always map circles and lines to circles and lines, where $a, b, c$ and $d$ are complex numbers such that $a d-b c \neq 0$ .

(ii) Show that the transformation

\zeta=\frac{z-\alpha}{\bar{\alpha} z-1}, \quad|\alpha|<1

maps the unit disk centered at $z=0$ onto itself.

(iii) Deduce a conformal transformation that maps the non-concentric annular domain $\Omega=\{|z|<1,|z-c|>c\}, 0<c<1 / 2$ , to a concentric annular domain.

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Paper 2, Section II, B

Complex Analysis or Complex Methods | Part IB, 2015

(i) A function $f(z)$ has a pole of order $m$ at $z=z_{0}$ . Derive a general expression for the residue of $f(z)$ at $z=z_{0}$ involving $f$ and its derivatives.

(ii) Using contour integration along a contour in the upper half-plane, determine the value of the integral

I=\int_{0}^{\infty} \frac{(\ln x)^{2}}{\left(1+x^{2}\right)^{2}} \mathrm{~d} x

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Paper 1, Section I, B

Complex Analysis or Complex Methods | Part IB, 2014

Let $f(z)$ be an analytic/holomorphic function defined on an open set $D$ , and let $z_{0} \in D$ be a point such that $f^{\prime}\left(z_{0}\right) \neq 0$ . Show that the transformation $w=f(z)$ preserves the angle between smooth curves intersecting at $z_{0}$ . Find such a transformation $w=f(z)$ that maps the second quadrant of the unit disc (i.e. $|z|<1, \pi / 2<\arg (z)<\pi)$ to the region in the first quadrant of the complex plane where $|w|>1$ (i.e. the region in the first quadrant outside the unit circle).

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Paper 1, Section II, B

Complex Analysis or Complex Methods | Part IB, 2014

By choice of a suitable contour show that for $a>b>0$

\int_{0}^{2 \pi} \frac{\sin ^{2} \theta d \theta}{a+b \cos \theta}=\frac{2 \pi}{b^{2}}\left[a-\sqrt{a^{2}-b^{2}}\right]

Hence evaluate

\int_{0}^{1} \frac{\left(1-x^{2}\right)^{1 / 2} x^{2} d x}{1+x^{2}}

using the substitution $x=\cos (\theta / 2)$ .

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Paper 2, Section II, B

Complex Analysis or Complex Methods | Part IB, 2014

By considering a rectangular contour, show that for $0<a<1$ we have

\int_{-\infty}^{\infty} \frac{e^{a x}}{e^{x}+1} d x=\frac{\pi}{\sin \pi a}

Hence evaluate

\int_{0}^{\infty} \frac{d t}{t^{5 / 6}(1+t)}

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Paper 1, Section I, $2 \mathrm{D}$

Complex Analysis or Complex Methods | Part IB, 2013

Classify the singularities (in the finite complex plane) of the following functions: (i) $\frac{1}{(\cosh z)^{2}}$ ; (ii) $\frac{1}{\cos (1 / z)}$ ; (iii) $\frac{1}{\log z} \quad(-\pi<\arg z<\pi)$ ; (iv) $\frac{z^{\frac{1}{2}}-1}{\sin \pi z} \quad(-\pi<\arg z<\pi)$ .

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Paper 1, Section II, E

Complex Analysis or Complex Methods | Part IB, 2013

Suppose $p(z)$ is a polynomial of even degree, all of whose roots satisfy $|z|<R$ . Explain why there is a holomorphic (i.e. analytic) function $h(z)$ defined on the region $R<|z|<\infty$ which satisfies $h(z)^{2}=p(z)$ . We write $h(z)=\sqrt{p(z)}$

By expanding in a Laurent series or otherwise, evaluate

\int_{C} \sqrt{z^{4}-z} d z

where $C$ is the circle of radius 2 with the anticlockwise orientation. (Your answer will be well-defined up to a factor of $\pm 1$ , depending on which square root you pick.)

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Paper 2, Section II, 13D Let

Complex Analysis or Complex Methods | Part IB, 2013

I=\oint_{C} \frac{e^{i z^{2} / \pi}}{1+e^{-2 z}} d z

where $C$ is the rectangle with vertices at $\pm R$ and $\pm R+i \pi$ , traversed anti-clockwise.

(i) Show that $I=\frac{\pi(1+i)}{\sqrt{2}}$ .

(ii) Assuming that the contribution to $I$ from the vertical sides of the rectangle is negligible in the limit $R \rightarrow \infty$ , show that

\int_{-\infty}^{\infty} e^{i x^{2} / \pi} d x=\frac{\pi(1+i)}{\sqrt{2}}

(iii) Justify briefly the assumption that the contribution to $I$ from the vertical sides of the rectangle is negligible in the limit $R \rightarrow \infty$ .

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Paper 1, Section I, A

Complex Analysis or Complex Methods | Part IB, 2012

Find a conformal transformation $\zeta=\zeta(z)$ that maps the domain $D, 0<\arg z<\frac{3 \pi}{2}$ , on to the strip $0<\operatorname{Im}(\zeta)<1$ .

Hence find a bounded harmonic function $\phi$ on $D$ subject to the boundary conditions $\phi=0, A$ on $\arg z=0, \frac{3 \pi}{2}$ , respectively, where $A$ is a real constant.

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Paper 1, Section II, 13A

Complex Analysis or Complex Methods | Part IB, 2012

Using Cauchy's integral theorem, write down the value of a holomorphic function $f(z)$ where $|z|<1$ in terms of a contour integral around the unit circle, $\zeta=e^{i \theta} .$

By considering the point $1 / \bar{z}$ , or otherwise, show that

f(z)=\frac{1}{2 \pi} \int_{0}^{2 \pi} f(\zeta) \frac{1-|z|^{2}}{|\zeta-z|^{2}} \mathrm{~d} \theta

By setting $z=r e^{i \alpha}$ , show that for any harmonic function $u(r, \alpha)$ ,

u(r, \alpha)=\frac{1}{2 \pi} \int_{0}^{2 \pi} u(1, \theta) \frac{1-r^{2}}{1-2 r \cos (\alpha-\theta)+r^{2}} \mathrm{~d} \theta

if $r<1$ .

Assuming that the function $v(r, \alpha)$ , which is the conjugate harmonic function to $u(r, \alpha)$ , can be written as

v(r, \alpha)=v(0)+\frac{1}{\pi} \int_{0}^{2 \pi} u(1, \theta) \frac{r \sin (\alpha-\theta)}{1-2 r \cos (\alpha-\theta)+r^{2}} \mathrm{~d} \theta

deduce that

f(z)=i v(0)+\frac{1}{2 \pi} \int_{0}^{2 \pi} u(1, \theta) \frac{\zeta+z}{\zeta-z} \mathrm{~d} \theta

[You may use the fact that on the unit circle, $\zeta=1 / \bar{\zeta}$ , and hence

\left.\frac{\zeta}{\zeta-1 / \bar{z}}=-\frac{\bar{z}}{\bar{\zeta}-\bar{z}} \cdot\right]

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Paper 2, Section II, A

Complex Analysis or Complex Methods | Part IB, 2012

By a suitable choice of contour show that, for $-1<\alpha<1$ ,

\int_{0}^{\infty} \frac{x^{\alpha}}{1+x^{2}} \mathrm{~d} x=\frac{\pi}{2 \cos (\alpha \pi / 2)}

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Paper 1, Section I, A

Complex Analysis or Complex Methods | Part IB, 2011

Derive the Cauchy-Riemann equations satisfied by the real and imaginary parts of a complex analytic function $f(z)$ .

If $|f(z)|$ is constant on $|z|<1$ , prove that $f(z)$ is constant on $|z|<1$ .

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Paper 1, Section II, A

Complex Analysis or Complex Methods | Part IB, 2011

(i) Let $-1<\alpha<0$ and let

\begin{aligned} &f(z)=\frac{\log (z-\alpha)}{z} \text { where }-\pi \leqslant \arg (z-\alpha)<\pi \\ &g(z)=\frac{\log z}{z} \quad \text { where }-\pi \leqslant \arg (z)<\pi \end{aligned}

Here the logarithms take their principal values. Give a sketch to indicate the positions of the branch cuts implied by the definitions of $f(z)$ and $g(z)$ .

(ii) Let $h(z)=f(z)-g(z)$ . Explain why $h(z)$ is analytic in the annulus $1 \leqslant|z| \leqslant R$ for any $R>1$ . Obtain the first three terms of the Laurent expansion for $h(z)$ around $z=0$ in this annulus and hence evaluate

\oint_{|z|=2} h(z) d z

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Paper 2, Section II, A

Complex Analysis or Complex Methods | Part IB, 2011

(i) Let $C$ be an anticlockwise contour defined by a square with vertices at $z=x+i y$ where

|x|=|y|=\left(2 N+\frac{1}{2}\right) \pi

for large integer $N$ . Let

I=\oint_{C} \frac{\pi \cot z}{(z+\pi a)^{4}} d z

Assuming that $I \rightarrow 0$ as $N \rightarrow \infty$ , prove that, if $a$ is not an integer, then

\sum_{n=-\infty}^{\infty} \frac{1}{(n+a)^{4}}=\frac{\pi^{4}}{3 \sin ^{2}(\pi a)}\left(\frac{3}{\sin ^{2}(\pi a)}-2\right) .

(ii) Deduce the value of

\sum_{n=-\infty}^{\infty} \frac{1}{\left(n+\frac{1}{2}\right)^{4}}

(iii) Briefly justify the assumption that $I \rightarrow 0$ as $N \rightarrow \infty$ .

[Hint: For part (iii) it is sufficient to consider, at most, one vertical side of the square and one horizontal side and to use a symmetry argument for the remaining sides.]

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Paper 1, Section I, A

Complex Analysis or Complex Methods | Part IB, 2010

(a) Write down the definition of the complex derivative of the function $f(z)$ of a single complex variable.

(b) Derive the Cauchy-Riemann equations for the real and imaginary parts $u(x, y)$ and $v(x, y)$ of $f(z)$ , where $z=x+i y$ and

f(z)=u(x, y)+i v(x, y)

(c) State necessary and sufficient conditions on $u(x, y)$ and $v(x, y)$ for the function $f(z)$ to be complex differentiable.

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Paper 1, Section II, A

Complex Analysis or Complex Methods | Part IB, 2010

Calculate the following real integrals by using contour integration. Justify your steps carefully.

(a)

I_{1}=\int_{0}^{\infty} \frac{x \sin x}{x^{2}+a^{2}} d x, \quad a>0

(b)

I_{2}=\int_{0}^{\infty} \frac{x^{1 / 2} \log x}{1+x^{2}} d x

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Paper 2, Section II, A

Complex Analysis or Complex Methods | Part IB, 2010

(a) Prove that a complex differentiable map, $f(z)$ , is conformal, i.e. preserves angles, provided a certain condition holds on the first complex derivative of $f(z)$ .

(b) Let $D$ be the region

D:=\{z \in \mathbb{C}:|z-1|>1 \text { and }|z-2|<2\}

Draw the region $D$ . It might help to consider the two sets

\begin{aligned} &C(1):=\{z \in \mathbb{C}:|z-1|=1\} \\ &C(2):=\{z \in \mathbb{C}:|z-2|=2\} \end{aligned}

(c) For the transformations below identify the images of $D$ .

Step 1: The first map is $f_{1}(z)=\frac{z-1}{z}$ ,

Step 2: The second map is the composite $f_{2} f_{1}$ where $f_{2}(z)=\left(z-\frac{1}{2}\right) i$ ,

Step 3: The third map is the composite $f_{3} f_{2} f_{1}$ where $f_{3}(z)=e^{2 \pi z}$ .

(d) Write down the inverse map to the composite $f_{3} f_{2} f_{1}$ , explaining any choices of branch.

[The composite $f_{2} f_{1}$ means $f_{2}\left(f_{1}(z)\right)$ .]

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Paper 1, Section I, D

Complex Analysis or Complex Methods | Part IB, 2009

Let $f(z)=u(x, y)+i v(x, y)$ , where $z=x+i y$ , be an analytic function of $z$ in a domain $D$ of the complex plane. Derive the Cauchy-Riemann equations relating the partial derivatives of $u$ and $v$ .

For $u=e^{-x} \cos y$ , find $v$ and hence $f(z)$ .

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Paper 1, Section II, D

Complex Analysis or Complex Methods | Part IB, 2009

Consider the real function $f(t)$ of a real variable $t$ defined by the following contour integral in the complex $s$ -plane:

f(t)=\frac{1}{2 \pi i} \int_{\Gamma} \frac{e^{s t}}{\left(s^{2}+1\right) s^{1 / 2}} d s,

where the contour $\Gamma$ is the line $s=\gamma+i y,-\infty<y<\infty$ , for constant $\gamma>0$ . By closing the contour appropriately, show that

f(t)=\sin (t-\pi / 4)+\frac{1}{\pi} \int_{0}^{\infty} \frac{e^{-r t} d r}{\left(r^{2}+1\right) r^{1 / 2}}

when $t>0$ and is zero when $t<0$ . You should justify your evaluation of the inversion integral over all parts of the contour.

By expanding $\left(r^{2}+1\right)^{-1} r^{-1 / 2}$ as a power series in $r$ , and assuming that you may integrate the series term by term, show that the two leading terms, as $t \rightarrow \infty$ , are

f(t) \sim \sin (t-\pi / 4)+\frac{1}{(\pi t)^{1 / 2}}+\cdots

[You may assume that $\int_{0}^{\infty} x^{-1 / 2} e^{-x} d x=\pi^{1 / 2}$ .]

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Paper 2, Section II, D

Complex Analysis or Complex Methods | Part IB, 2009

Show that both the following transformations from the $z$ -plane to the $\zeta$ -plane are conformal, except at certain critical points which should be identified in both planes, and in each case find a domain in the $z$ -plane that is mapped onto the upper half $\zeta$ -plane:

\begin{aligned} &\text { (i) } \zeta=z+\frac{b^{2}}{z} \\ &\text { (ii) } \zeta=\cosh \frac{\pi z}{b} \end{aligned}

where $b$ is real and positive.

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1.I.3C

Complex Analysis or Complex Methods | Part IB, 2008

Given that $f(z)$ is an analytic function, show that the mapping $w=f(z)$

(a) preserves angles between smooth curves intersecting at $z$ if $f^{\prime}(z) \neq 0$ ;

(b) has Jacobian given by $\left|f^{\prime}(z)\right|^{2}$ .

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1.II.13C

Complex Analysis or Complex Methods | Part IB, 2008

By a suitable choice of contour show the following:

(a)

\int_{0}^{\infty} \frac{x^{1 / n}}{1+x^{2}} d x=\frac{\pi}{2 \cos (\pi / 2 n)}

where $n>1$ ,

(b)

\int_{0}^{\infty} \frac{x^{1 / 2} \log x}{1+x^{2}} d x=\frac{\pi^{2}}{2 \sqrt{2}}

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2.II.14C

Complex Analysis or Complex Methods | Part IB, 2008

Let $f(z)=1 /\left(e^{z}-1\right)$ . Find the first three terms in the Laurent expansion for $f(z)$ valid for $0<|z|<2 \pi$ .

Now let $n$ be a positive integer, and define

\begin{aligned} &f_{1}(z)=\frac{1}{z}+\sum_{r=1}^{n} \frac{2 z}{z^{2}+4 \pi^{2} r^{2}} \\ &f_{2}(z)=f(z)-f_{1}(z) \end{aligned}

Show that the singularities of $f_{2}$ in $\{z:|z|<2(n+1) \pi\}$ are all removable. By expanding $f_{1}$ as a Laurent series valid for $|z|>2 n \pi$ , and $f_{2}$ as a Taylor series valid for $|z|<2(n+1) \pi$ , find the coefficients of $z^{j}$ for $-1 \leq j \leq 1$ in the Laurent series for $f$ valid for $2 n \pi<|z|<2(n+1) \pi$ .

By estimating an appropriate integral around the contour $|z|=(2 n+1) \pi$ , show that

\sum_{r=1}^{\infty} \frac{1}{r^{2}}=\frac{\pi^{2}}{6}

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1.I.3F

Complex Analysis or Complex Methods | Part IB, 2007

For the function

f(z)=\frac{2 z}{z^{2}+1},

determine the Taylor series of $f$ around the point $z_{0}=1$ , and give the largest $r$ for which this series converges in the disc $|z-1|<r$ .

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1.II.13F

Complex Analysis or Complex Methods | Part IB, 2007

By integrating round the contour $C_{R}$ , which is the boundary of the domain

D_{R}=\left\{z=r e^{i \theta}: 0<r<R, \quad 0<\theta<\frac{\pi}{4}\right\}

evaluate each of the integrals

\int_{0}^{\infty} \sin x^{2} d x, \quad \int_{0}^{\infty} \cos x^{2} d x

[You may use the relations $\int_{0}^{\infty} e^{-r^{2}} d r=\frac{\sqrt{\pi}}{2}$ and $\sin t \geq \frac{2}{\pi} t$ for $\left.0 \leq t \leq \frac{\pi}{2} \cdot\right]$

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2.II.14F

Complex Analysis or Complex Methods | Part IB, 2007

Let $\Omega$ be the half-strip in the complex plane,

\Omega=\left\{z=x+i y \in \mathbb{C}:-\frac{\pi}{2}<x<\frac{\pi}{2}, \quad y>0\right\}

Find a conformal mapping that maps $\Omega$ onto the unit disc.

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1.I.3D

Complex Analysis or Complex Methods | Part IB, 2006

Let $L$ be the Laplace operator, i.e., $L(g)=g_{x x}+g_{y y}$ . Prove that if $f: \Omega \rightarrow \mathbf{C}$ is analytic in a domain $\Omega$ , then

L\left(|f(z)|^{2}\right)=4\left|f^{\prime}(z)\right|^{2}, \quad z \in \Omega .

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1.II.13D

Complex Analysis or Complex Methods | Part IB, 2006

By integrating round the contour involving the real axis and the line $\operatorname{Im}(z)=2 \pi$ , or otherwise, evaluate

\int_{-\infty}^{\infty} \frac{e^{a x}}{1+e^{x}} d x, \quad 0<a<1 .

Explain why the given restriction on the value $a$ is necessary.

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2.II.14D

Complex Analysis or Complex Methods | Part IB, 2006

Let $\Omega$ be the region enclosed between the two circles $C_{1}$ and $C_{2}$ , where

C_{1}=\{z \in \mathbf{C}:|z-i|=1\}, \quad C_{2}=\{z \in \mathbf{C}:|z-2 i|=2\}

Find a conformal mapping that maps $\Omega$ onto the unit disc.

[Hint: you may find it helpful first to map $\Omega$ to a strip in the complex plane. ]

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1.I.3F

Complex Analysis or Complex Methods | Part IB, 2005

State the Cauchy integral formula.

Using the Cauchy integral formula, evaluate

\int_{|z|=2} \frac{z^{3}}{z^{2}+1} d z

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1.II.13F

Complex Analysis or Complex Methods | Part IB, 2005

Determine a conformal mapping from $\Omega_{0}=\mathbf{C} \backslash[-1,1]$ to the complex unit disc $\Omega_{1}=\{z \in \mathbf{C}:|z|<1\} .$

[Hint: A standard method is first to map $\Omega_{0}$ to $\mathbf{C} \backslash(-\infty, 0]$ , then to the complex right half-plane $\{z \in \mathbf{C}: \operatorname{Re} z>0\}$ and, finally, to $\left.\Omega_{1} .\right]$

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2.II.14F

Complex Analysis or Complex Methods | Part IB, 2005

Let $F=P / Q$ be a rational function, where $\operatorname{deg} Q \geqslant \operatorname{deg} P+2$ and $Q$ has no real zeros. Using the calculus of residues, write a general expression for

\int_{-\infty}^{\infty} F(x) e^{i x} d x

in terms of residues and briefly sketch its proof.

Evaluate explicitly the integral

\int_{-\infty}^{\infty} \frac{\cos x}{4+x^{4}} d x

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Complex Analysis Or Complex Methods

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