User:Mystman666



I'm a total n00b at this, but willing to learn (at a slooow pace.. university takes a lot of my time :P)

I apologize if I do something wrong >_<

My interests in Wikipedia:
Looking over my edit history, it seems I've mostly done a lot of fixing of typos, and occasionally removing some POV/incorrect sentences. There aren't that many subjects that I have knowledge of, and that don't already have good articles, so I haven't written a lot. I sometimes nose around in Articles for Deletion, and will occasionaly comment on the Talk Pages of larger articles if I think that it could be improved in some way.

Lately my actions on wikipedia seem to be restricted to removing vandalism and assorted rule-breaching stuff. I should really start typing some articles but again, my knowledge is quite restricted... that, and I'm afraid that with my writing skills, everything I write is going to be rewritten anyway. ^^

Basic make-up
Ok, so that isn't that impressive. For a newbie like me it is though.

I think the Wikipedia style of inserting images looks really neat. Especially because it's so consistent across articles. I'm glad that I also (kinda) know how it works.

Trying to create subpages: User:Mystman666/steam

Signatures
I still want the time and date in superscript, but I get the idea that isn't possible (not with the standard way of signing using four tildes anyway). -- Mystman666 (Talk) 18:32, 6 January 2006 (UTC)

Using the math editor
Ok, I needed a formula for an essay, and then remembered all those formulas with sexy makeup I saw in wikipedia articles.. Fast forward half an hour, and I kinda know how to use the math-make-up-language (just kinda)

$$-\frac {\hbar^2}{2m}\left( \frac {\partial^2 \Psi(x,y,z)}{\partial x^2}+ \frac {\partial^2 \Psi(x,y,z)}{\partial y^2}+\frac {\partial^2 \Psi(x,y,z)}{\partial z^2}\right)+ U(x,y,z)\Psi(x,y,z) = E_{n_{x},n_{y},n_{z}}\Psi(x,y,z)$$

$$ -Ln(\frac{I}{I_{0}}) = -\mu d \qquad \qquad \mathbf{(6)} $$

$$ I = I_{0}e^{-\mu_{p}(d_{p1}+d_{p2})}e^{-\mu_{a}d_{a}} \qquad \qquad \mathbf{(7)} $$

$$ d_{a} = \frac {Ln(\frac{I}{I_{0}}) + 2\mu_{p}d_{t}}{2\mu_{p}-\mu_{a}} \qquad \qquad \mathbf{(8)} $$

$$ T =\sum_{i=1}^I \sum_{j=1}^J \frac {(n_{ij} - E(N_{ij}))^2}{E(N_{ij})} $$

$$ E(N_{ij}) = \frac {n_{i.} n_{.j}}{n_{..}} $$

$$ T ~ Chi^2_{(I-1)(J-1)} $$

$$ F =\frac {SS_B / (I - 1)}{SS_W/(I(J-1))} \overset{H_0} {\sim} F_{I-1, I(J-1)} $$