4:58 AM
1

What would be the best book, article, or otherwise to reference for the specific construction of the classifying space for a discrete group $G$ which goes as follows?: Regard $G$ as a category with one object whose morphisms are the elements of $G$. Construct the simplicial sets $NG$ (i.e., the ...

2 hours later…
7:01 AM
2

This post did not quite seem to answer my question. If we have $\quad a+bi\in\mathbb{C}\quad$ can ordering be done the way of Pythagorean triples $\quad A^2+B^2=C^2?\quad$ There are infinite triples for each of $\quad (C-B),\space (C-A),\space\text{and}\space (B\pm A)\quad$ but these may be fur...

4 hours later…
10:43 AM
2

I am stuck with this problem from my son's homework: Given $p$ and $q$ are prime numbers, prove that $\sqrt[3]{pq}$ is irrational Could someone please shed some light? Thanks!

3 hours later…
1:13 PM
3

Find all the even perfect numbers of the form $a^a +1$, where $a \in \mathbb{N}$. Can you please provide me some hint or idea on how to find such numbers.

4 hours later…
5:43 PM
2

Rudin gives the following definition for a right hand limit and left hand limit, and discontinuities (see attached image) So, to show a function has type 2 discontinuities I need to show that the right hand and left hand limits don't exist. Should the $q$ in the image be an $x$? If not then I am...

5:58 PM
10

Imagine the following data frame: # ID v1 v2 v3 v4 #1 H 0 0 d 0 #2 I 0 0 0 0 #3 J d 0 0 0 #4 K 0 0 0 d #5 L 0 d 0 0 There is either one or no "d" per row. For each row, I want to convert everything after d to NA. Desired result: # ID v1 v2 v3 v4 #1 H 0 0 d NA...

5 hours later…
10:43 PM
2

Let $f(x) = \left\{\begin{array}{ll} x + 2 & -3 < x < -2 \\ -x -2 & -2 \leq x < 0 \\ x + 2 & 0 \leq x < 1 \end{array}\right.$ I want to show that $f$ has a discontinuity at $x=0$ but is continuous at all other points in $(-3,1)$ Attempt: If $f$ was continuous at $0$ then $\lim_{x \to 0}f(x) = f(0... 2 Let$A$be a commutative ring with$f,g\in A[x]$monics. Consider the$A$-linear endomorphism$\mu_g^{(f)}\in \mathrm{End}_A\tfrac{A[x]}{\langle f\rangle}$given by multiplication by$g$. For monics$f_1,f_2\in A[x]$, how to directly prove that$\det \mu_g^{(f_1f_2)}=\det\mu_g^{(f_1)}\det\mu_g^{(...