Behavior of coupled DEVS

Last updated December 23, 2022

In theoretical computer science, DEVS is closed under coupling [Zeigper84] [ZPK00]. In other words, given a coupled DEVS model $N$ , its behavior is described as an atomic DEVS model $M$ . For a given coupled DEVS $N$ , once we have an equivalent atomic DEVS $M$ , behavior of $M$ can be referred to behavior of atomic DEVS which is based on Timed Event System.

View1: Total states = states * elapsed times

Given a coupled DEVS model $N=<X,Y,D,\{M_{i}\},C_{xx},C_{yx},C_{yy},Select>$ , its behavior is described as an atomic DEVS model $M=<X,Y,S,s_{0},ta,\delta _{ext},\delta _{int},\lambda >$

where

$X$ and $Y$ are the input event set and the output event set, respectively.
$S={\underset {i\in D}{\times }}Q_{i}$ is the partial state set where $Q_{i}=\{(s_{i},t_{ei})|s_{i}\in S_{i},t_{ei}\in (\mathbb {T} \cap [0,ta_{i}(s_{i})])\}$ is the total state set of component $i\in D$ (Refer to View1 of Behavior of DEVS), where $\mathbb {T} =[0,\infty )$ is the set of non-negative real numbers.
$s_{0}={\underset {i\in D}{\times }}q_{0i}$ is the initial state set where $q_{0i}=(s_{0i},0)$ is the total initial state of component $i\in D$ .
$ta:S\rightarrow \mathbb {T} ^{\infty }$ is the time advance function, where $\mathbb {T} ^{\infty }=[0,\infty ]$ is the set of non-negative real numbers plus infinity. Given $s=(\ldots ,(s_{i},t_{ei}),\ldots )$ ,
$ta(s)=\min\{ta_{i}(si)-t_{ei}|i\in D\}.$

$\delta _{ext}:Q\times X\rightarrow S$ is the external state function. Given a total state $q=(s,t_{e})$ where $s=(\ldots ,(s_{i},t_{ei}),\ldots ),t_{e}\in (\mathbb {T} \cap [0,ta(s)])$ , and input event $x\in X$ , the next state is given by
$\delta _{ext}(q,x)=s'=(\ldots ,(s_{i}',t_{ei}'),\ldots )$

where

(s_{i}',t_{ei}')={\begin{cases}(\delta _{ext}(s_{i},t_{ei},x_{i}),0)&{\text{if }}(x,x_{i})\in C_{xx}\\(s_{i},t_{ei})&{\text{otherwise}}.\end{cases}}

Given the partial state $s=(\ldots ,(s_{i},t_{ei}),\ldots )\in S$ , let $IMM(s)=\{i\in D|ta_{i}(s_{i})=ta(s)\}$ denote the set of imminent components. The firing component $i^{*}\in D$ which triggers the internal state transition and an output event is determined by

i^{*}=Select(IMM(s)).

$\delta _{int}:S\rightarrow S$ is the internal state function. Given a partial state $s=(\ldots ,(s_{i},t_{ei}),\ldots )$ , the next state is given by
$\delta _{int}(s)=s'=(\ldots ,(s_{i}',t_{ei}'),\ldots )$

where

(s_{i}',t_{ei}')={\begin{cases}(\delta _{int}(s_{i}),0)&{\text{if }}i=i^{*}\\(\delta _{ext}(s_{i},t_{ei},x_{i}),0)&{\text{if }}(\lambda _{i^{*}}(s_{i^{*}}),x_{i})\in C_{yx}\\(s_{i},t_{ei})&{\text{otherwise}}.\end{cases}}

$\lambda :S\rightarrow Y^{\phi }$ is the output function. Given a partial state $s=(\ldots ,(s_{i},t_{ei}),\ldots )$ ,
$\lambda (s)={\begin{cases}\phi &{\text{if }}\lambda _{i^{*}}(s_{i^{*}})=\phi \\C_{yy}(\lambda _{i^{*}}(s_{i^{*}}))&{\text{otherwise}}.\end{cases}}$

View2: Total states = states * lifespan * elapsed times

Given a coupled DEVS model $N=<X,Y,D,\{M_{i}\},C_{xx},C_{yx},C_{yy},Select>$ , its behavior is described as an atomic DEVS model $M=<X,Y,S,s_{0},ta,\delta _{ext},\delta _{int},\lambda >$

where

$X$ and $Y$ are the input event set and the output event set, respectively.
$S={\underset {i\in D}{\times }}Q_{i}$ is the partial state set where $Q_{i}=\{(s_{i},t_{si},t_{ei})|s_{i}\in S_{i},t_{si}\in \mathbb {T} ^{\infty },t_{ei}\in (\mathbb {T} \cap [0,t_{si}])\}$ is the total state set of component $i\in D$ (Refer to View2 of Behavior of DEVS).
$s_{0}={\underset {i\in D}{\times }}q_{0i}$ is the initial state set where $q_{0i}=(s_{0i},ta_{i}(s_{0i}),0)$ is the total initial state of component $i\in D$ .
$ta:S\rightarrow \mathbb {T} ^{\infty }$ is the time advance function. Given $s=(\ldots ,(s_{i},t_{si},t_{ei}),\ldots )$ ,
$ta(s)=\min\{t_{si}-t_{ei}|i\in D\}.$

$\delta _{ext}:Q\times X\rightarrow S\times \{0,1\}$ is the external state function. Given a total state $q=(s,t_{s},t_{e})$ where $s=(\ldots ,(s_{i},t_{si},t_{ei}),\ldots ),t_{s}\in \mathbb {T} ^{\infty },t_{e}\in (\mathbb {T} \cap [0,t_{s}])$ , and input event $x\in X$ , the next state is given by
$\delta _{ext}(q,x)=((\ldots ,(s_{i}',t_{si}',t_{ei}'),\ldots ),b)$

where

(s_{i}',t_{si}',t_{ei}')={\begin{cases}(s_{i}',ta_{i}(s_{i}'),0)&{\text{if }}(x,x_{i})\in C_{xx},\delta _{ext}(s_{i},t_{si},t_{ei},x_{i})=(s_{i}',1)\\(s_{i}',t_{si},t_{ei})&{\text{if }}(x,x_{i})\in C_{xx},\delta _{ext}(s_{i},t_{si},t_{ei},x_{i})=(s_{i}',0)\\(s_{i},t_{si},t_{ei})&{\text{otherwise}}\end{cases}}

and

b={\begin{cases}1&{\text{if }}\exists i\in D:(x,x_{i})\in C_{xx},\delta _{ext}(s_{i},t_{si},t_{ei},x_{i})=(s_{i}',1)\\0&{\text{otherwise}}.\end{cases}}

Given the partial state $s=(\ldots ,(s_{i},t_{si},t_{ei}),\ldots )\in S$ , let $IMM(s)=\{i\in D|t_{si}-t_{ei}=ta(s)\}$ denote the set of imminent components. The firing component $i^{*}\in D$ which triggers the internal state transition and an output event is determined by

i^{*}=Select(IMM(s)).

$\delta _{int}:S\rightarrow S$ is the internal state function. Given a partial state $s=(\ldots ,(s_{i},t_{si},t_{ei}),\ldots )$ , the next state is given by
$\delta _{int}(s)=s'=(\ldots ,(s_{i}',t_{si}',t_{ei}'),\ldots )$

where

(s_{i}',t_{si}',t_{ei}')={\begin{cases}(s_{i}',ta_{i}(s_{i}'),0)&{\text{if }}i=i^{*},\delta _{int}(s_{i})=s_{i}',\\(s_{i}',ta_{i}(s_{i}'),0)&{\text{if }}(\lambda _{i^{*}}(s_{i^{*}}),x_{i})\in C_{yx},\delta _{ext}(s_{i},t_{si},t_{ei},x_{i})=(s',1)\\(s_{i}',t_{si},t_{ei})&{\text{if }}(\lambda _{i^{*}}(s_{i^{*}}),x_{i})\in C_{yx},\delta _{ext}(s_{i},t_{si},t_{ei},x_{i})=(s',0)\\(s_{i},t_{si},t_{ei})&{\text{otherwise}}.\end{cases}}

$\lambda :S\rightarrow Y^{\phi }$ is the output function. Given a partial state $s=(\ldots ,(s_{i},t_{si},t_{ei}),\ldots )$ ,
$\lambda (s)={\begin{cases}\phi &{\text{if }}\lambda _{i^{*}}(s_{i^{*}})=\phi \\C_{yy}(\lambda _{i^{*}}(s_{i^{*}}))&{\text{otherwise}}.\end{cases}}$

Time passage

Since in a coupled DEVS model with non-empty sub-components, i.e., $|D|>0$ , the number of clocks which trace their elapsed times are multiple, so time passage of the model is noticeable.

For View1

Given a total state $q=(s,t_{e})\in Q$ where $s=(\ldots ,(s_{i},t_{ei}),\ldots )$

If unit event segment $\omega$ is the null event segment, i.e. $\omega =\epsilon _{[t,t+dt]}$ , the state trajectory in terms of Timed Event System is

\Delta (q,\omega )=((\ldots ,(s_{i},t_{ei}+dt),\ldots ),t_{e}+dt).

For View2

Given a total state $q=(s,t_{s},t_{e})\in Q$ where $s=(\ldots ,(s_{i},t_{si},t_{ei}),\ldots )$

If unit event segment $\omega$ is the null event segment, i.e. $\omega =\epsilon _{[t,t+dt]}$ , the state trajectory in terms of Timed Event System is

\Delta (q,\omega )=((\ldots ,(s_{i},t_{si},t_{ei}+dt),\ldots ),t_{s},t_{e}+dt).

Remarks

The behavior of a couple DEVS network whose all sub-components are deterministic DEVS models can be non-deterministic if $Select(IMM(s))$ is non-deterministic.

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References

[Zeigler84] Bernard Zeigler (1984). Multifacetted Modeling and Discrete Event Simulation. Academic Press, London; Orlando. ISBN 978-0-12-778450-2.
[ZKP00] Bernard Zeigler; Tag Gon Kim; Herbert Praehofer (2000). Theory of Modeling and Simulation (second ed.). Academic Press, New York. ISBN 978-0-12-778455-7.

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Behavior of coupled DEVS

Contents

View1: Total states = states * elapsed times

View2: Total states = states * lifespan * elapsed times

Time passage

Remarks

See also

Related Research Articles

References