User:Cbogart2

Hi, I'm Chris Bogart. I'm also cbogart but it won't email me the password, so I can't get back in to that account. I'm a student at Oregon State University. More about me

I'm using this as a sandbox
Here's a link to the band, Tool.

Headline text
$$e^x dy/dx$$--Cbogart2 04:34, 22 August 2005 (UTC)

Deterministic DEVS and Non-deterministic DEVS
Let $$A$$ and $$B$$ be two arbitrary sets. Then function $$f:A \rightarrow B$$ is called deterministic if give an $$a \in A$$, the values of callings $$f(a)$$ at different times are identical. Otherwise, $$f$$ is called non-deterministic.

A DEVS $$M=$$ is called deterministic if $$ta$$, $$\delta_{ext}$$, $$\delta_{int}$$ and $$\lambda$$ are deterministic. Otherwise, $$ M $$ is called non-deterministic.

The atomic DEVS model for player A of Fig. 1 is given Player=$$$$ such that
 * The atomic DEVS Model for Ping-Pong Players

$$ X = \{?receive\}\, $$

$$Y=\{!send\}\, $$

$$S=\{(d,\sigma)| d \in \{Wait,Send\}, \sigma \in \mathbb{T}^\infty\}\, $$ and $$s_0=(Send,0.1)\, $$

$$ta(s)=\sigma \text{ for all } s \in S\, $$

$$\delta_{ext}((Wait,\sigma),t_e),?receive)=(Send,0.1)\, $$

$$\delta_{ext}((Send,\sigma,t_e),?receive)=(Send, \sigma-t_e)\,$$

$$\delta_{int}(Send,\sigma)=(Wait,\infty),\delta_{int}(Wait,\sigma)=(Send,0.1)\,$$

$$\lambda(Send,\sigma)=?send,\lambda_{int}(Wait,\sigma)=\phi\,$$

Both of Player A and Player B are deterministic DEVS models.