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| # Introduction {#sec-chap_1_Intro} | |
| In this work, a tool called \glsfirst{cnmc} is further developed. | |
| The overall goal, in very brief terms, is to generate a model, which is able to | |
| predict the trajectories of general dynamical systems. The model | |
| shall be capable of predicting the trajectories when a model parameter | |
| value is changed. | |
| Some basics about dynamical systems are covered in | |
| subsection [-@sec-subsec_1_1_1_Principles] and in-depth explanations about \gls{cnmc} are given in | |
| chapter [-@sec-chap_2_Methodology]. \newline | |
| However, for a short and broad introduction to \gls{cnmc} the workflow depicted in figure @fig-fig_1_CNMC_Workflow shall be highlighted. | |
| The input it receives is data of a dynamical system or space state vectors for a range of model parameter values. The two main important outcomes are some accuracy measurements and the predicted trajectory for each desired model parameter value. | |
| Any inexperienced user may only have a look at the predicted trajectories to | |
| quickly decide visually whether the prediction matches the trained data. Since \gls{cnmc} is written in a modular manner, meaning it can be regarded as | |
| a black-box function, it can easily be integrated into other existing codes or | |
| workflows. \newline | |
| {#fig-fig_1_CNMC_Workflow} | |