Development of a method for approximate solution of nonlinear ordinary differential equations using pendulum motion as an example

Abstract: 4thermophysical properties, etc. In turn, this causes variation in a wide range of the process parameters subject to control. In such a situation, application of the results obtained by analysis of linear models is very problematic and even unfeasible in most cases.The search for new approaches to analysis of nonlinear models is an important element in solution of the problem of optimal control of power equipment using non-certified fuel of a variable composition. Literature review and problem statementAn effe… Show more

“…-for 60° -by 13 %; -for 90° -by 9 %. The results reported in [11] show the manifestation of a synergistic effect from combining a «standard» model linearization technology and using a special nondimensionalization method [10]. Moreover, one can talk about the emergence for such a combination of research tools.…”

“…However, the cited paper does not consider the possibility of using the benefits obtained in the process of linearizing the model equations. This possibility is considered in work [11] using an example of studying the motion of a mathematical pendulum. The non-linearity of the model was determined by the possibility of taking into consideration the large initial deviation of the pendulum from the position of equilibrium (by 30°, 60°, and 90°) in the absence and presence of dissipative forces.…”

Constructing a method for solving the riccati equations to describe objects parameters in an analytical form

“…-for 60° -by 13 %; -for 90° -by 9 %. The results reported in [11] show the manifestation of a synergistic effect from combining a «standard» model linearization technology and using a special nondimensionalization method [10]. Moreover, one can talk about the emergence for such a combination of research tools.…”

“…However, the cited paper does not consider the possibility of using the benefits obtained in the process of linearizing the model equations. This possibility is considered in work [11] using an example of studying the motion of a mathematical pendulum. The non-linearity of the model was determined by the possibility of taking into consideration the large initial deviation of the pendulum from the position of equilibrium (by 30°, 60°, and 90°) in the absence and presence of dissipative forces.…”

Constructing a method for solving the riccati equations to describe objects parameters in an analytical form

“…Therefore, comparison of results, obtained based on (16), of the magnitudes, given in [2], is valid. It should only be noted that during cooling the moment the process is over is considered to be a point when temperature reaches magnitude θ = ⋅θ = The comparison was conducted by determining relative error ε of calculating Fo based on (16) relative to Fo 1 . In the process of comparing, we chose the magnitude of k from (13) that ensures minimum magnitude of relative error ε.…”

“…Nevertheless, in addition to it, it makes it possible, with respect to (15), to perform calculations for an infinite cylinder and a sphere. Table 1 Comparison of results of precise [2] and approximate (16) calculations of nondimensionalized time of the end of the process of heating the bodies It follows from results shown in Table 1 that an error of determining the time of the end of heating the bodies using expression (16) compared to the results of precise analytical solution does not exceed 4 % over the entire examined range of change in Bi.…”

“…We shall nondimensionalize time variable according to the method proposed in [16] using a complex included in equation (8) that has a time dimensionality:…”

Development of the method of approximate solution to the nonstationary problem on heat transfer through a flat wall

Development of Models and Methods for Automated Control of Heat Supply System with Optimization of Technical Means Structure