Within the scope of current research, the scientific and applied problem of balancing multisubject polyfactorial environments of software products’ complex support was considered, in the context of a more global scientific and applied problem of automation and intellectualization of the complex support of software products, as well as a human-machine interaction. The relevant object of research in this work – is the process of balancing multisubject polyfactorial environments of software products’ complex support. An appropriate method has been developed to ensure the possibility of balancing (and further potential automation of these processes) of multisubject polyfactorial environments, which provides the possibility of solving the declared scientific and applied problem of current research. In particular, the necessary algorithm for balancing the investigated multisubject polyfactorial environments has been developed, as well as the corresponding basic mathematical model, which provides the possibility of interpreting, researching, and modelling the processes of balancing of the multisubject polyfactorial environments of software products’ complex support. A practical approbation of the developed method has been carried out on the example of solving the experimental applied problem of identification and monitoring “of-the-trend” dynamics of the deficient component during the automated balancing of the investigated multisubject polyfactorial support environment of the research software complex. The prospects for further research directions related to possible ways of potential improvement(s) and enhancement(s), as well as practical application of the developed method (for balancing multisubject polyfactorial environments of software products’ complex support), have been considered. In particular, as one of the potential directions of further research, we see the development of additional algorithmic and software supply that would ensure possibilities for better modelling the researched processes of various balancing multisubject polyfactorial environments for different software’s complex support, in order to find potential evolution ways of the proposed concept.
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