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Complex analysis, holomorphic functions, automorphic group actions and forms, pseudoconvexity, complex geometry, analytic spaces, analytic sheaves.
5
votes
Accepted
Weierstrass Theorem
Why don't you start with a function with zeros at the integers,
for instance $\sin\pi z$, and then somehow eliminate the zero at $r$?
5
votes
Analytic continuation via square of absolute value
Rather obviously not: if $f(z)=\sqrt{z}$ on $U$, the
plane slit along the negative real axis, then $|f(z)|^2=|z|$
is real analytic on $V$ the plane with the origin removed
but $f$ does not analyticall …
4
votes
Accepted
Relationships between the roots of an entire function and the roots of its derivative
I don't know if there are any general results about these, but
when $f$ is a polynomial, these must be in essence results about
symmetric functions. If $f(z)=z^n+a_{n-1} z^{n-1}+\cdots+a_1z+a_0$
then …
9
votes
Accepted
Can curves induced by analytic maps wiggle infinitely across a line?
The image of $[0,1]$ is compact and so must contain the purported
accumulation point. It makes no loss to assume that $\gamma(t)=t$,
$f(0)=0$ is the accumulation point, and the line in question
is the …
4
votes
Accepted
Points at twice the distance from (-1, 0) that they are from (1, 0) in hyperbolic geometry
This is a bit basic for MO, but I'll present my solution.
I don't understand what the OP's notation is so I'll
use my favourite model for hyperbolic space, the Poincaré
upper half plane ('cos I like m …
3
votes
Coprimality and squarefree numbers
These probabilities equal $\zeta(2)^{-1}$ and
$\zeta_{\mathbb{Q}(i)}(2)^{-1}$ where $\zeta$ is the Riemann zeta-function
and $\zeta_K$ is the Dedekind zeta function for the number field $K$.
The proof …