On the computation of the parameterized differential Galois group for a second-order linear differential equation with differential parameters

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• 作者：Carlos E. Arreche ^{cearrech@math.ncsu.edu" class="auth_mail" title="E-mail the corresponding author}
• 关键词：12H20 ; 34M15 ; 34M03 ; 20H20 ; 13N10 ; 33F10 ; 37K20
• 刊名：Journal of Symbolic Computation
• 出版年：2016
• 出版时间：July-August 2016
• 年：2016
• 卷：75
• 期：Complete
• 页码：25-55
• 全文大小：716 K

文摘

We present algorithms to compute the differential Galois group G associated via the parameterized Picard–Vessiot theory to a parameterized second-order linear differential equation where the coefficients r₁$r_1$ and r₀$r_0$ belong to the field of rational functions F(x)$F(x)$ over a computable Π-field F of characteristic zero, and the finite set of commuting derivations Π is thought of as consisting of derivations with respect to parameters. This work relies on earlier procedures developed by Dreyfus and by the present author to compute G   under the assumption that r₁=0$r_1=0$, which guarantees that G   is unimodular. When r₁≠0$r_1\ne 0$, we reinterpret a classical change-of-variables procedure in Galois-theoretic terms in order to reduce the computation of G to the computation of an associated unimodular differential Galois group H  . We establish a parameterized version of the Kolchin–Ostrowski theorem and apply it to give more direct proofs than those found in the literature of the fact that the required computations can be performed effectively. We then extract from these algorithms a complete set of criteria to decide whether any of the solutions to a parameterized second-order linear differential equation is Π-transcendental over the underlying Π-field of F(x)$F(x)$. We give various examples of computation and some applications to differential transcendence.