{"title":"可容许综合问题中开关曲面的显式形式","authors":"V. I. Korobov, O. Vozniak","doi":"10.26565/2221-5646-2022-96-03","DOIUrl":null,"url":null,"abstract":"In this article we consider the problem related to positional synthesis and controllability function method and more precisely to admissible maximum principle. Unlike the more common approach the admissible maximum principle method gives discontinuous solutions to the positional synthesis problem. Let us consider the canonical system of linear equations $\\dot{x}_i=x_{i+1}, i=\\overline{1,n-1}, \\dot{x}_n=u$ with constraints $|u| \\le d$. The problem for an arbitrary linear system $\\dot{x} = A x + b u$ can be simplified to this problem for the canonical system. A controllability function $\\Theta(x)$ is given as a unique positive solution of some equation $\\Phi(x,\\Theta) = 0$. The control is chosen to minimize derivative of the function $\\Theta(x)$ and can be written as $u(x) = -d \\text{ sign}(s(x,\\Theta(x)))$. The set of points $s(x,\\Theta(x)) = 0$ is called the switching surface, and it determines the points where control changes its sign. Normally it \\mbox{contains} the variable $\\Theta$ which is given implicitly as the solution of equation $\\Phi(x, \\Theta) = 0$. Our aim in this paper is to find a representation of the switching surface that does not depend on the function $\\Theta(x)$. We call this representation the explicit form. In our case the expressions $\\Phi(x, \\Theta)$ and $s(x, \\Theta)$ are both polynomials with respect to $\\Theta$, so this problem is related to the problem of finding conditions when two polynomials have a common positive root. Earlier the solution for the 2-dimensional case was known. But during the exploration it was found out that for systems of higher dimensions there exist certain difficulties. In this article the switching surface for the three dimensional case is presented and researched. It is shown that this switching surface is a sliding surface (according to Filippov's definition). Also the other ways of constructing the switching surface using the interpolation and approximation are proposed and used for finding the trajectories of concrete points.","PeriodicalId":33522,"journal":{"name":"Visnik Kharkivs''kogo natsional''nogo universitetu imeni VN Karazina Seriia Ekonomika","volume":"44 1","pages":""},"PeriodicalIF":0.0000,"publicationDate":"2022-12-24","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"The explicit form of the switching surface in admissible synthesis problem\",\"authors\":\"V. I. Korobov, O. Vozniak\",\"doi\":\"10.26565/2221-5646-2022-96-03\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"In this article we consider the problem related to positional synthesis and controllability function method and more precisely to admissible maximum principle. Unlike the more common approach the admissible maximum principle method gives discontinuous solutions to the positional synthesis problem. Let us consider the canonical system of linear equations $\\\\dot{x}_i=x_{i+1}, i=\\\\overline{1,n-1}, \\\\dot{x}_n=u$ with constraints $|u| \\\\le d$. The problem for an arbitrary linear system $\\\\dot{x} = A x + b u$ can be simplified to this problem for the canonical system. A controllability function $\\\\Theta(x)$ is given as a unique positive solution of some equation $\\\\Phi(x,\\\\Theta) = 0$. The control is chosen to minimize derivative of the function $\\\\Theta(x)$ and can be written as $u(x) = -d \\\\text{ sign}(s(x,\\\\Theta(x)))$. The set of points $s(x,\\\\Theta(x)) = 0$ is called the switching surface, and it determines the points where control changes its sign. Normally it \\\\mbox{contains} the variable $\\\\Theta$ which is given implicitly as the solution of equation $\\\\Phi(x, \\\\Theta) = 0$. Our aim in this paper is to find a representation of the switching surface that does not depend on the function $\\\\Theta(x)$. We call this representation the explicit form. In our case the expressions $\\\\Phi(x, \\\\Theta)$ and $s(x, \\\\Theta)$ are both polynomials with respect to $\\\\Theta$, so this problem is related to the problem of finding conditions when two polynomials have a common positive root. Earlier the solution for the 2-dimensional case was known. But during the exploration it was found out that for systems of higher dimensions there exist certain difficulties. In this article the switching surface for the three dimensional case is presented and researched. It is shown that this switching surface is a sliding surface (according to Filippov's definition). 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引用次数: 0
摘要
本文考虑了位置综合和可控性函数法的相关问题,更确切地说,考虑了可容许最大值原理。与一般的方法不同,可容许极大原理法给出了位置综合问题的不连续解。让我们考虑带约束的正则线性方程组$\dot{x}_i=x_{i+1}, i=\overline{1,n-1}, \dot{x}_n=u$$|u| \le d$。对于任意线性系统$\dot{x} = A x + b u$的问题可以简化为正则系统的问题。给出了可控性函数$\Theta(x)$作为方程$\Phi(x,\Theta) = 0$的唯一正解。选择控制以最小化函数$\Theta(x)$的导数,可以写成$u(x) = -d \text{ sign}(s(x,\Theta(x)))$。点的集合$s(x,\Theta(x)) = 0$被称为切换面,它决定了控制改变其符号的点。通常是\mbox{contains}变量$\Theta$隐式地给出方程$\Phi(x, \Theta) = 0$的解。我们在本文中的目标是找到不依赖于$\Theta(x)$函数的切换曲面的表示。我们称这种表示为显式。在我们的例子中,表达式$\Phi(x, \Theta)$和$s(x, \Theta)$都是关于$\Theta$的多项式,所以这个问题与寻找两个多项式有一个公正根的条件有关。之前二维情况的解是已知的。但在探索过程中发现,对于高维系统存在一定的困难。本文提出并研究了三维情况下的开关曲面。证明了该开关曲面是一个滑动曲面(根据Filippov的定义)。此外,还提出了利用插值法和近似法构造切换曲面的其他方法,并将其用于寻找具体点的轨迹。
The explicit form of the switching surface in admissible synthesis problem
In this article we consider the problem related to positional synthesis and controllability function method and more precisely to admissible maximum principle. Unlike the more common approach the admissible maximum principle method gives discontinuous solutions to the positional synthesis problem. Let us consider the canonical system of linear equations $\dot{x}_i=x_{i+1}, i=\overline{1,n-1}, \dot{x}_n=u$ with constraints $|u| \le d$. The problem for an arbitrary linear system $\dot{x} = A x + b u$ can be simplified to this problem for the canonical system. A controllability function $\Theta(x)$ is given as a unique positive solution of some equation $\Phi(x,\Theta) = 0$. The control is chosen to minimize derivative of the function $\Theta(x)$ and can be written as $u(x) = -d \text{ sign}(s(x,\Theta(x)))$. The set of points $s(x,\Theta(x)) = 0$ is called the switching surface, and it determines the points where control changes its sign. Normally it \mbox{contains} the variable $\Theta$ which is given implicitly as the solution of equation $\Phi(x, \Theta) = 0$. Our aim in this paper is to find a representation of the switching surface that does not depend on the function $\Theta(x)$. We call this representation the explicit form. In our case the expressions $\Phi(x, \Theta)$ and $s(x, \Theta)$ are both polynomials with respect to $\Theta$, so this problem is related to the problem of finding conditions when two polynomials have a common positive root. Earlier the solution for the 2-dimensional case was known. But during the exploration it was found out that for systems of higher dimensions there exist certain difficulties. In this article the switching surface for the three dimensional case is presented and researched. It is shown that this switching surface is a sliding surface (according to Filippov's definition). Also the other ways of constructing the switching surface using the interpolation and approximation are proposed and used for finding the trajectories of concrete points.
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