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| bio | website | |
|---|---|---|
| location | ||
| age | 22 | |
| visits | member for | 1 year, 11 months |
| seen | 40 mins ago | |
| stats | profile views | 5,640 |
MathSE chatroom co-owner alongside robjohn.
My answers with expository content (may update later):
- "Make-believe" free constructions in algebra
- Sets of lecture notes and articles
- Applications, motivations of the tensor product
- On tensoring with torsion, divisibility and fractions
- Terse description of local fields as $\bullet$-adic complections
- Cycle decomposition & orders of permutations as lcms
- Relation between ${\bf F}_p$ and ${\bf Z}_p$ via Witt vectors
- Cyclotomic structure of the $p$-adics ${\bf Q}_p$
- Representation theory generalizes 1D characters
- $S_n$ is complete for $n\ne2,6$
- Abelian implies Frattini = prime subgroups
- Ford circles, hyperbolic geometry & wt. $0$ modular forms
- Motivation, explanation of asymptotic notation
- Permutation centralizers via internal wreath products
- Characters of symmetric and exterior powers
- What's interesting about the zeros of $\zeta(s)$
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9h |
comment |
What is the difference between a surface and the graph of a function? The "graph of a function" is presumably the surface comprised of points $(x,y,z)$ which satisfy a relation $z=f(x,y)$. Such a surface will pass a "vertical line test," so no two points on the surface will lie on a given vertical line. However the sphere fails this vertical line test so it is not the graph of the function, though one can graph the upper or lower hemispheres individually. |
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9h |
answered | Is a set of prime numbers open in Furstenberg's topology? |
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10h |
comment |
Applying Möbius' theorem The equations $z=1+i,z=1-i,z=-1-i$ determine three points, not three lines. These three points are not collinear (there is no line that passes through all three), so I don't really understand your argument. |
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10h |
revised |
Applying Möbius' theorem deleted 15 characters in body; edited title |
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10h |
comment |
2-colorable belongs to $\mathsf P$ [...] If at any stage, the procedure asks us to color a vertex a different color than what it already is, the graph is not $2$-colorable, but otherwise if we finish coloring the graph then it is $2$-colorable. I am not familiar with computational complexity theory so I don't know how to frame that in a way that the complexity involved in each stage is transparent, unfortunately. |
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10h |
comment |
2-colorable belongs to $\mathsf P$ My understanding: The problem is to show that deciding whether a graph is $2$-colorable or not can be done in time bounded by a polynomial in the number of vertices $n$. You're interested in how to frame the method you have in mind, but your description of your reasoning ("the other is B and so on") seems a bit vague. Here's the method that comes to my mind: color one vertex say white (arbitrarily), then color its adjacent vertices black, then color their adjacent vertices white, and so on. [...] |
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15h |
answered | Determining the group homomorphism in semidirect product |
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15h |
comment |
Determining the group homomorphism in semidirect product The action of $h\in H$ on $N$ inside $N\rtimes H$ is conjugation. That is, "$h(n)=hnh^{-1}$." |
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15h |
comment |
What is the exact definition of polynomial functions? Tangentially, an oft-overlooked point is that the evaluation map is not a ring homomorphism if $R$ is noncommutative. |
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16h |
revised |
Strong characterization of $\mathbb C$ with respect to $\mathbb R$ edited tags |
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18h |
answered | Normal subgroup if conjugate subgroup is subset |
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18h |
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Normal subgroup if conjugate subgroup is subset It's possible Qiaochu was thinking of the something like the semidirect product of additive groups ${\bf Q}\rtimes{\bf Z}$, where $1\in\bf Z$ acts on $x\in{\bf Q}$ as multiplication by $2$. I'm pretty sure I've seen this example (with ${\bf Z}[1/2]$ instead of $\bf Q$ for some reason IIRC) in an MSE answer. |
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19h |
comment |
Group of mapping is a subset of symmetric group @PaulS With your functions, $i(1)=2=i(2)$ so $g(i(1))=g(i(2))$. Can you extrapolate from this example to see that $i$ not injective implies $gi$ not injective? |
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19h |
revised |
Group of mapping is a subset of symmetric group rolled back to a previous revision |
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20h |
revised |
Group of mapping is a subset of symmetric group edited body |
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20h |
answered | Group of mapping is a subset of symmetric group |
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20h |
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Group of mapping is a subset of symmetric group Interesting, thanks - I did not realize there could be subgroups in the monoid of functions on a set that did not contain the identity mapping. |
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20h |
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Group of mapping is a subset of symmetric group If $G$ is a group comprised of mappings then those mappings must be invertible (since every element of a group must have an inverse) hence $G$ is a subset of the collection of invertible mappings, in symbols that is $G\subseteq{\rm Sym}(X)$. The fact that all of $G$'s elements are bijective functions is automatically true, there is no "if" about it, which makes the phrasing here seem strange. |
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20h |
comment |
General solution of differential equation of order 3 Almost, $dX=(\int_0^ue(s)ds)'=e(u)$ (no $e(0)$ involved) |
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21h |
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General solution of differential equation of order 3 @Vrouvrou Please read en.wikipedia.org/wiki/Integration_by_parts (I use $X$ and $Y$ where Wikipedia uses $u$ and $v$, since I already have the letters $u$ and $v$ in use.) |
