Sandbox for drafts of long, complex posts

Question

This sandbox is intended for saving drafts of long, complex posts, especially posts whose composition takes a long time. It serves to localize to one thread the front-page "bumps" caused by edits to drafts of such posts, so that they may be easily ignored. Also, it helps to guard against losing longly-composed posts due to system crashes.

When you are happy with your draft here, you may simply copy the code and paste it to the desired location.

Proper Use of the Sandbox

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   This answer is free for anyone to use

   is sufficient. Periodically users may go through and free up answer slots that have not been edited in, say, over one month. But you can aid in the smooth running of this sandbox by clearing away your drafts when you are finished with them.

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Answer 1

\begin{align} 2^{10}10^{2018}+7^4 &= 2^{10}100^{1009}+(50-1)^2 \\ &= 2^{1019}50^{1009} + 50^2 -2\cdot50 + 1 \\ &= 50(2^{1019}50^{1008} + 48)+1 \end{align}

factoring $50(3n+2)+1$ \begin{array}{r} 50( 2)+1 &= & 101 \\ 50( 5)+1 &= & 251 \\ 50( 8)+1 &= & 401 \\ 50(11)+1 &= & 551 &= &19\cdot29 &= &(24-5)(24+5) \\ 50(14)+1 &= & 701 \\ 50(17)+1 &= & 851 &= &23\cdot37 &= &(30-7)(30+7) \\ 50(20)+1 &= &1001 &= &7\cdot 11 \cdot 13 \\ 50(23)+1 &= &1151 \\ 50(26)+1 &= &1301 \\ 50(29)+1 &= &1451 \\ 50(32)+1 &= &1601 \\ 50(35)+1 &= &1751 &= &17\cdot 103 &= &(60-43)(60+43) \\ 50(38)+1 &= &1901 \\ 50(41)+1 &= &2051 &= &7\cdot 293 &= &(150-143)(150+143) \\ 50(44)+1 &= &2201 &= &31\cdot 71 &= &(51-20)(51+20) \\ 50(47)+1 &= &2351 \\ 50(50)+1 &= &2501 &= &41\cdot 61 &= &(51-10)(51+10) \\ \end{array}

We may as well use the points $P_k = (\cos(\theta k), \sin(\theta k))$ where $\theta = \dfrac{2\pi}{5}$ and $k \in \{0,1,2,3,4\}$.

$$\frac{XA+XB}{XC+XD+XE}$$

Let $\theta = \dfrac{2\pi}{5}$. Then we can define \begin{align} A &= (\cos(2\theta),\sin(2\theta)) \\ B &= (\cos(3\theta),\sin(3\theta)) \\ C &= (\cos(4\theta),\sin(4\theta)) \\ D &= (\cos(0\theta),\sin(0\theta)) \\ E &= (\cos(1\theta),\sin(1\theta)) \\ \end{align}

$\begin{array}{ccc} \theta & \cos \theta & \sin \theta \\ 0 \cdot\dfrac{2 \pi}{5} & 1 & 0 \\ 1 \cdot\dfrac{2 \pi}{5} & \dfrac{\sqrt 5 - 1}{4} & \sqrt{\dfrac{5+\sqrt 5}{8}} \\ 2 \cdot\dfrac{2 \pi}{5} & -\dfrac{\sqrt 5 + 1}{4} & \sqrt{\dfrac{5-\sqrt 5}{8}} \\ 3 \cdot\dfrac{2 \pi}{5} & -\dfrac{\sqrt 5 + 1}{4} & -\sqrt{\dfrac{5-\sqrt 5}{8}} \\ 4 \cdot\dfrac{2 \pi}{5} & \dfrac{\sqrt 5 - 1}{4} & -\sqrt{\dfrac{5+\sqrt 5}{8}} \\ \end{array}$

Answer 2

This entry is available for anyone who knows how to enjoy a bit of Lorem ipsum in life from time to time.

Answer 3

This slot is as vacant as the expression of someone who's been staring at the same line of a proof for three hours.

Answer 4

This entry is available for anyone to commandeer since Oct. 17th, 2018.

Answer 5

This space free for whoever wants it

Answer 6

This answer is available for anyone to use.

Answer 7

This slot is open for anyone to use.

Answer 8

This space is freely open to everyone.

Answer 9

This answer is available for anyone to use.

Answer 10

This answer is free for anyone to use.

Answer 11

This answer is available for use by anyone.

Answer 12

This entry is available for anyone to commandeer since Oct. 13th, 2018.

Answer 13

This entry is available for everyone.

Answer 14

This entry is free for anyone to commandeer since Oct. 27th, 2018

Answer 15

This entry is free for anyone to use.

Answer 16

Function $f$ is defined as $$f(x)=\frac{1}{(x-1)^3(x^3+2x^2+x+1)}\tag 1$$ Note that $$x^3+2x^2+x+1=(x+1)(x^2+x+1)\tag 2$$ and so $$f(x)=\frac{1}{(x-1)^3(x+1)(x^2+x+1)}\tag 3$$ and also $$f(x)=\frac{1}{(x-1)}\cdot\frac{1}{(x^2-1)}\cdot\frac{1}{(x^3-1)}=\sum_{i=0}^\infty x^i \cdot\sum_{k=0}^\infty x^{2k} \cdot\sum_{j=0}^\infty x^{3j}$$

$$\frac{1}{(x-1)^3(x+1)(x^2+x+1}=\frac{A_1}{(x-1)}+\frac{A_2}{(x-1)^1}+\frac{A_3}{(x-1)^3}+\frac{B}{(x+1)}+\frac{Cx+D}{(x^2+x+1)}$$ $$1=A_1(x-1)^2(x+1)(x^2+x+1)+A_2(x-1)(x+1)(x^2+x+1)+A_3(x+1)(x^2+x+1)+B(x-1)^3(x^2+x+1)+(Cx+D)(x-1)^3(x+1)$$

Answer 17

It's been a long time since I last did this stuff, but nobody better seems to have turned up, so I'll have a go.

I'll give the box $\square \phi$ its usual meaning here: "when I translate $\phi$ into the formal system using Gödel numbers, then there is a collection of mechanical transformations inside the formal system that together form an internal-system-proof of $\phi$'s quotation". I will also refer to the formal system in question in the first person, with the pronoun "I".

Then the formula $\square (\square \phi \to \phi) \to \square \phi$ should be read as:

If there is a number which encodes a proof that "having a number which encodes a proof of $\phi$ means I can actually prove $\phi$", then there is a number which encodes a proof of $\phi$.

Or, a bit more loosely,

If I, internally, can prove that my proof of $\phi$ respects the logic in which I operate (so my proof of $\phi$ means that in my surrounding logic, $\phi$ is actually true), then in fact there is a proof of $\phi$ that I will be satisfied with.

This is more concretely understood through its universal quantification, Löb's theorem (which is true in any system rich enough to support Peano arithmetic):

If I can prove within myself that my own proof-checking process respects the semantics of the logic in which I operate, then the logic realises that actually I can satisfy myself of any statement at all.

Specifically, $\square (\square \phi \to \phi)$ means "I contain a proof that my proofs are semantically valid in the surrounding logic", while $\square \square \phi \to \square \phi$ means "it's true in the surrounding logic that if I want to prove $\phi$, it's enough to prove provability-of-$\phi$".

The two statements were very unlikely to be the same: one is talking about proof within the system, and one is talking about facts of the surrounding logic.