Difference between revisions of "Schwarz equation"
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The non-linear ordinary differential equation of the third order | The non-linear ordinary differential equation of the third order | ||
| − | + | $$\frac{z'''}{z'}-\frac32\left(\frac{z''}{z'}\right)^2=2I(t).\label{1}\tag{1}$$ | |
| − | Its left-hand side is called the Schwarzian derivative of the function | + | Its left-hand side is called the Schwarzian derivative of the function $z(t)$ and is denoted by $\{z,t\}$. H.A. Schwarz applied this equation in his studies [[#References|[1]]]. |
| − | If | + | If $x_1(t),x_2(t)$ is a [[Fundamental system of solutions|fundamental system of solutions]] of the second-order linear differential equation |
| − | + | $$x''+p(t)x'+q(t)x=0,\quad p\in C^1,\quad q\in C,\label{2}\tag{2}$$ | |
| − | then on any interval where | + | then on any interval where $x_2(t)\neq0$, the function |
| − | + | $$z(t)=\frac{x_1(t)}{x_2(t)}\label{3}\tag{3}$$ | |
| − | satisfies the Schwarz equation | + | satisfies the Schwarz equation \eqref{1}, where |
| − | + | $$I(t)=q(t)-\frac14p^2(t)-\frac12p'(t)$$ | |
| − | is the so-called invariant of the linear equation | + | is the so-called invariant of the linear equation \eqref{2}. Conversely, any solution of the Schwarz equation \eqref{1} can be presented in the form \eqref{3}, where $x_1(t),x_2(t)$ are linearly independent solutions of \eqref{2}. Solutions of a Schwarz equation with a rational right-hand side in the complex plane are closely connected with the problem of describing the functions that conformally map the upper half-plane into a polygon bounded by a finite number of segments of straight lines and arcs of circles. |
====References==== | ====References==== | ||
Latest revision as of 17:29, 14 February 2020
The non-linear ordinary differential equation of the third order
$$\frac{z'''}{z'}-\frac32\left(\frac{z''}{z'}\right)^2=2I(t).\label{1}\tag{1}$$
Its left-hand side is called the Schwarzian derivative of the function $z(t)$ and is denoted by $\{z,t\}$. H.A. Schwarz applied this equation in his studies [1].
If $x_1(t),x_2(t)$ is a fundamental system of solutions of the second-order linear differential equation
$$x''+p(t)x'+q(t)x=0,\quad p\in C^1,\quad q\in C,\label{2}\tag{2}$$
then on any interval where $x_2(t)\neq0$, the function
$$z(t)=\frac{x_1(t)}{x_2(t)}\label{3}\tag{3}$$
satisfies the Schwarz equation \eqref{1}, where
$$I(t)=q(t)-\frac14p^2(t)-\frac12p'(t)$$
is the so-called invariant of the linear equation \eqref{2}. Conversely, any solution of the Schwarz equation \eqref{1} can be presented in the form \eqref{3}, where $x_1(t),x_2(t)$ are linearly independent solutions of \eqref{2}. Solutions of a Schwarz equation with a rational right-hand side in the complex plane are closely connected with the problem of describing the functions that conformally map the upper half-plane into a polygon bounded by a finite number of segments of straight lines and arcs of circles.
References
| [1] | H.A. Schwarz, "Ueber diejenigen Fälle, in welchen die Gaussische hypergeometrische Reihe eine algebraische Function ihres vierten Elements darstellt (nebst zwei Figurtafeln)" J. Reine Angew. Math. , 75 (1873) pp. 292–335 |
| [2] | V.V. Golubev, "Vorlesungen über Differentialgleichungen im Komplexen" , Deutsch. Verlag Wissenschaft. (1958) (Translated from Russian) |
Comments
For the relation with conformal mapping see [a2] and Christoffel–Schwarz formula.
References
| [a1] | E. Hille, "Lectures on ordinary differential equations" , Addison-Wesley (1969) |
| [a2] | Z. Nehari, "Conformal mapping" , Dover, reprint (1975) pp. Chapt. 7, §7 |
Schwarz equation. Encyclopedia of Mathematics. URL: http://encyclopediaofmath.org/index.php?title=Schwarz_equation&oldid=18412