Analysis the brachistochronic motion of a mechanical system with nonlinear nonholonomic constraint

Radulović, Radoslav; Zeković, D.N.; Lazarević, Mihailo P.; Segľa, Štefan; Jeremić, Bojan

doi:10.5937/fmet1404290r

Cited by 6 publications

(11 citation statements)

References 10 publications

(17 reference statements)

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“…Thus, comparing the obtained results, we can conclude that function ( ) y x found with the plus sign in formula (18) gives the maximum value to functional (7), and the function with the minus sign is the minimum value of all motion paths that correspond to the formulation of the presented variational problem.…”

Section: Problem Statementmentioning

confidence: 69%

“…(the start and finish points lie on axis ). OX 1) First, in the formula (18), we consider the case with the plus sign.…”

Section: Problem Statementmentioning

confidence: 99%

“…We use formula (7) to calculate it with the selected data of the studied problem. In other words, function ( ) f x is selected by formula (15), function ( ) y x is chosen by formula (18)…”

Section: Problem Statementmentioning

confidence: 99%

“…As a result of calculating integral (7), we obtain 2.46 T (units of time). 2) Now consider the case with the minus sign in formula (18).…”

Section: Problem Statementmentioning

confidence: 99%

“…Therefore, in this case, only five members of the Taylor series should be taken into account without losing the accuracy of the approximation of the desired function ( ) y x . Now we calculate the time of the boat moving along this trajectory, obtained with the minus sign in front of the integral in formula (18). After calculations we get a smaller result:…”

Section: Problem Statementmentioning

confidence: 99%

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The Brachistochronic Movement of a Material Point in the Horizontal Vector Field of a Mobile Fluid

Legeza¹,

Atamaniuk²

2019

KPI SN

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Background. Since the brachistochronic motion of a material point in a flat vector field of a mobile fluid was not previously considered, the formulated variational problem of searching for extremal trajectories in such a formulation is new and relevant. Objective. The aim of the study is to obtain the algebraic equations of extremal trajectories of motion, along which the material point moves from a given starting point to a given finish point in the shortest possible time. Methods. The solution of the problem was carried out using classical methods of the calculus of variations (to obtain a differential equation for the motion of a material point), as well as using Taylor series (for approximate integration of the resulting differential equation). For a given variant of the boundary conditions, approximate algebraic equations of extremals of the motion of a material point were established in the form of segments of power series. A comparative analysis of the time of movement was carried out both along extreme trajectories and along an alternative shortest pathalong a straight line, which connects two given points of start and finish. Results. It is shown that the considered variational problem has two different solutions, which differ only in sign. At the same time, only one solution provides the minimum time for the movement of a material point between the given start and finish points. Studies have also found that the extremal trajectory of the brachistochronic movement of a point is not straight and has an oscillatory character. Conclusions. The proposed approach allows plotting in advance such a logistical route of a material point (motorboat) in a flat vector field of a mobile fluid between the given start and finish points, which ensures the minimum travel time between them. In this case, the extremal trajectory will not necessarily be the shortest line that connects the start and finish points.

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Section: Problem Statementmentioning

confidence: 69%

“…(the start and finish points lie on axis ). OX 1) First, in the formula (18), we consider the case with the plus sign.…”

Section: Problem Statementmentioning

confidence: 99%

“…We use formula (7) to calculate it with the selected data of the studied problem. In other words, function ( ) f x is selected by formula (15), function ( ) y x is chosen by formula (18)…”

Section: Problem Statementmentioning

confidence: 99%

“…As a result of calculating integral (7), we obtain 2.46 T (units of time). 2) Now consider the case with the minus sign in formula (18).…”

Section: Problem Statementmentioning

confidence: 99%

Section: Problem Statementmentioning

confidence: 99%

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The Brachistochronic Movement of a Material Point in the Horizontal Vector Field of a Mobile Fluid

Legeza¹,

Atamaniuk²

2019

KPI SN

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A new approach for the determination of the global minimum time for the Chaplygin sleigh brachistochrone problem

Radulović

Šalinić

Obradović

et al. 2016

Mathematics and Mechanics of Solids

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A new approach for the determination of the global minimum time for the case of the brachistochronic motion of the Chaplygin sleigh is presented. The new approach is based on the use of the shooting method in solving the corresponding two-point boundary-value problem and defining either the crossing points of surfaces or the crossing points space of curves in a three-dimensional space of two costate variables and the time of the brachistochronic motion of the sleigh. A number of examples for multiple extremals of the Chaplygin sleigh brachistochrone problem are provided. In these examples, the global minimum is the solution to which the minimum time of motion corresponds.

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Realizing brachistochronic planar motion of a variable mass nonholonomic mechanical system by an ideal holonomic constraint with restricted reaction

Jeremić

Radulović

Zorić

et al. 2019

Filomat

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The paper considers realization of the brachistochronic motion of a nonholonomic mechanical system, composed of variable mass particles, by means of an ideal holonomic constraint with restricted reaction. It is assumed that the system performs planar motion in an arbitrary field of forces and that it has two degrees of freedom. In addition, the laws of the time-rate of mass variation of the particles, as well as relative velocities of the expelled and gained particles, respectively, are known. Restricted reaction of the holonomic constraint is taken for the scalar control. Applying Pontryagin's maximum principle and singular optimal control theory, the problem of brachistochronic motion is solved as a two-point boundary value problem (TPBVP). Since the reaction of the constraint is restricted, different types of control structures are examined, from singular to totally nonsingular. The considerations are illustrated via an example.

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Analysis the brachistochronic motion of a mechanical system with nonlinear nonholonomic constraint

Cited by 6 publications

References 10 publications

The Brachistochronic Movement of a Material Point in the Horizontal Vector Field of a Mobile Fluid

The Brachistochronic Movement of a Material Point in the Horizontal Vector Field of a Mobile Fluid

A new approach for the determination of the global minimum time for the Chaplygin sleigh brachistochrone problem

Realizing brachistochronic planar motion of a variable mass nonholonomic mechanical system by an ideal holonomic constraint with restricted reaction

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