Define dynamical systems.
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Sergiu Ivanov
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@ -344,3 +344,56 @@ keywords = {Boolean P systems, Boolean networks, Reachability, Complexity},
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url =
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{https://doi.org/10.1093/oxfordhb/9780199566600.001.0001},
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}
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@article{Zeeman1976,
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author = {Erik C. Zeeman},
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title = {Catastrophe theory},
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journal = {Scientific American},
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volume = {234(4)},
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pages = {65--83},
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year = {1976}
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}
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@misc{wikiDS,
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author = "{Wikipedia contributors}",
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title = "Dynamical system --- {Wikipedia}{,} The Free
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Encyclopedia",
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year = "2024",
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howpublished =
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"\url{https://en.wikipedia.org/w/index.php?title=Dynamical_system&oldid=1208607435}",
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note = "[Online; accessed 27-February-2024]"
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}
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@article{Thom1974,
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title = {Stabilité structurelle et morphogenèse},
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journal = {Poetics},
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volume = {3},
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number = {2},
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pages = {7-19},
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year = {1974},
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issn = {0304-422X},
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doi = {https://doi.org/10.1016/0304-422X(74)90010-2},
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url =
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{https://www.sciencedirect.com/science/article/pii/0304422X74900102},
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author = {René Thom}
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}
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@book{Brown2018,
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title = {A Modern Introduction to Dynamical Systems},
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author = {Richard J. Brown},
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isbn = {978-0198743286},
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publisher = {Oxford University Press},
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year = {2018}
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}
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@phdthesis{Riva22,
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author = {Sara Riva},
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title = {Factorisation of discrete dynamical systems. (Factorisation de syst{\`{e}}mes
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dynamiques discrets)},
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school = {C{\^{o}}te d'Azur University, Nice, France},
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year = {2022},
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url = {https://tel.archives-ouvertes.fr/tel-03937258},
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timestamp = {Wed, 25 Jan 2023 22:01:27 +0100},
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biburl = {https://dblp.org/rec/phd/hal/Riva22.bib},
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bibsource = {dblp computer science bibliography, https://dblp.org}
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}
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58
deal.tex
58
deal.tex
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@ -490,6 +490,63 @@ with Life, the Deal with Life framework can be adapted to
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characterizing and evaluating the interactions between other living
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systems, not necessarily involving the human.
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\subsection{Dynamical systems}
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\label{sec:ds}
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Following the spirit of~\cite{Thom1974,Zeeman1976}, I propose to use
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the language of abstract dynamical systems for the general framework
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of the Deal. In this subsection I quickly recall the main notions,
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and I refer to sources like~\cite{Brown2018,wikiDS} for more general
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and more detailed definitions.
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An \emph{abstract dynamical system} over the state space $X$ and time
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$T$ is a (partial) function $\Phi : X \times T \to X$ assigning to
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a state $s \in X$ the new state $\Phi(s, t)$ in which the system will
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be after time $t \in T$. The function $\Phi$ satisfies the following
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two natural properties:
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\begin{enumerate}
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\item $\Phi(s, 0) = s$: the system does not change its state in
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0 time,
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\item $\Phi(\Phi(s, t_1), t_2) = \Phi(s, t_1 + t_2)$: evolving the
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system for time $t_1$, then for time $t_2$ leads to the same state
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as evolving the systems for time $t_1 + t_2$.
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\end{enumerate}
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A common shape for a state is an $n$-vector of real parameters of
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a system---in which case $X \subseteq \mathbb{R}^n$---but no
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particular restrictions are imposed: $X$ may be a more a general
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algebraic object. In the most general setting, $T$ is a monoid, but
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it is rather customary for the time domain to be a contiguous infinite
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subset of either $\mathbb{Z}$ or $\mathbb{R}$. In the first case,
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$\Phi$ is usually called a discrete-time dynamical system, and in the
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second case $\Phi$ is called a continuous-time dynamical system.
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If additionally the state space $X$ of a discrete-time dynamical
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system $\Phi : X \times T \to T$ with $T \subseteq \mathbb{Z}$ is
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discrete (countable), then $\Phi$ is called a discrete dynamical
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system. Finally, if $X$ is a finite set, then $\Phi$ is called
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a finite dynamical system.
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In the case of discrete-time dynamical systems, the time variable can
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be interpreted as the number of evolution steps. More concretely, for
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a $t > 0$, $\Phi(s, t)$ can be seen as the state of the system after
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$t$ steps, while $\Phi(s, -t)$ can be seen as the state the system
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\emph{was in} $t$ steps ago. When $T = \mathbb{N}$, it is customary
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to see the discrete-time dynamical systems as the function
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$F : X \to X$, giving the state to which the dynamical system
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transitions from state $s \in X$: $F(s) = \Phi(s, 1)$
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(e.g,~\cite[Chapter~1]{Riva22}).
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Given a dynamical system $\Phi : X \times T \to X$ and a state
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$s \in X$, it is possible to construct the restricted function
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$\Phi_s : T \to X$, $\Phi_s(t) = \Phi(s, t)$, determining the
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\emph{trajectory} of $\Phi$ through $s$.
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$\Ima \Phi_s = \{\Phi(s, t) \mid t\in T\}$. If $T = \mathbb{Z}$ or
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$T = \mathbb{R}$, then the trajectory $\Ima \Phi_s$ can be interpreted
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as the set of all states through which $\Phi$ goes before and after
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reaching $s$. If $T = \mathbb{N}$, then the trajectory through $s$ is
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the iteration of $F$: $\{F^k(s) \mid k \in \mathbb{N}\}$, where
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$F^0(s) = s$, $F^1(s) = F(s)$, $F^2(s) = F(F(s))$, etc.
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\printbibliography[heading=subbibliography]
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\end{refsection}
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@ -497,4 +554,5 @@ systems, not necessarily involving the human.
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%%% Local Variables:
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%%% TeX-engine: luatex
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%%% TeX-master: "hdr"
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%%% reftex-default-bibliography: ("bib/dealb.bib" "bib/sivanov-dblp-mod.bib" "bib/sivanov-extra.bib")
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%%% End:
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