User:Jordanl122

Hiya, I really only edit books and story pages that I have enough authority to speak about.

TeX scribbles
Hey Yona, I couldn't get the equations to render in Open office, but here's the formal problem statement of phase 7,

$$Let\ \{A_{1},A_{2},...,A_{n}\} be\ a\ given\ number\ of\ inputs,\ $$ $$and\ let\ \{k_{1},k_{2},...,k_{n}\}be\ the\ corresponding\ number\ of\ values\ each A_{i}\ can\ assume. $$ $$Let\ \{{x_{k_{i}}}^{j} \}^{m_{k_{i}}}_{j=1} be\ the\ strictly\ increasing\ sequence\ which\ defines\ Rng(A_{i}) for\ some\ m_{k_{i}}\in \N $$ $$and\ let\ X: = \{\mathbf{x} = ({x_{k_{i}}}^j,{x_{k_{i}}}^j,...,{x_{k_{i}}}^j)| for\ all\ possible\ {x_{k_{i}}}^p\}$$ and let f:X→$$\mathbb{R}$$ the pre-defined fitness function.

Goal 1: Find x such that $$\max_{F(\mathbf{x})\in\mathbb R}\; F(\mathbf{x})$$ is approximated within a well defined error.

Goal 2: Determine all pairwise relations $$ (A_i,A_j) for\ i,j \in \{1,...,n\} $$

Goal 3: Determine all k-wise relations $$ (A_{i_1},A_{i_2},...,A_{i_k}) for\ i_1,i_2,...,i_k \in \{1,...,n\} $$ --- End of Problem

$$R: = \{f\in L^2(p)|\int_\Omega (g\circ f) dx= e\}$$

$$\sum_{i=1}^{n}i = \frac{n(n+1)}{2}$$

$$K: = \{\bigcup_{i\in\Z} k| k\in \R \}$$

$$(\forall x\in\N)(x\in\Z)$$

$$ I\ am\ you\leftrightarrow you\ are\ me $$

$$\oint_{\Omega\subseteq\R^3}f\bullet ds = \left |\frac{\partial x}{\partial t} + \frac{\partial f}{\partial s}\right|$$

if you recognize this one, I tip my hat to you:

$$\Theta\frac{d^2\phi}{dt^2} + \delta ^{*} \frac{d\phi}{dt} + \frac{\partial L}{\partial \alpha}(s_{1} - s_{2})\alpha = -\frac{\partial R}{\partial \beta}s_{3}\beta$$