The Mumford Dynamical System and Hyperelliptic Kleinian Functions

Pub Date : 2024-04-01 DOI:10.1134/S0016266323040032
V. M. Buchstaber
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Abstract

We develop a differential-algebraic theory of the Mumford dynamical system. In the framework of this theory, we introduce the \((P,Q)\)-recursion, which defines a sequence of functions \(P_1,P_2,\ldots\) given the first function \(P_1\) of this sequence and a sequence of parameters \(h_1,h_2,\dots\). The general solution of the \((P,Q)\)-recursion is shown to give a solution for the parametric graded Korteweg–de Vries hierarchy. We prove that all solutions of the Mumford dynamical \(g\)-system are determined by the \((P,Q)\)-recursion under the condition \(P_{g+1} = 0\), which is equivalent to an ordinary nonlinear differential equation of order \(2g\) for the function \(P_1\). Reduction of the \(g\)-system of Mumford to the Buchstaber–Enolskii–Leykin dynamical system is described explicitly, and its explicit \(2g\)-parameter solution in hyperelliptic Klein functions is presented.

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芒福德动力系统和超椭圆克莱因函数
摘要 我们发展了芒福德动力系统的微分代数理论。在这一理论的框架内,我们引入了((P,Q)\)-递归,它定义了一个函数序列(P_1,P_2,\ldots),给定了这个序列的第一个函数(P_1)和一个参数序列(h_1,h_2,\dots)。((P,Q)\)的一般解-递归的一般解给出了参数分级 Korteweg-de Vries 层次的解。我们证明,在 \((P,Q)\) -递归的条件下,芒福德动力学 \(g\) -系统的所有解都是由\((P,Q)\) -递归决定的。-条件下的(P_{g+1} = 0)递归决定的,这等价于函数 (P_1)的阶(2g)的普通非线性微分方程。将 Mumford 的 \(g\) - 系统还原为 Buchstaber-Enolskii-Leykin 动力系统,并给出了其在超椭圆 Klein 函数中的明确 \(2g\) - 参数解。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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