Meromorphic solutions to theq-Painlevé equations around the origin

“…Classifying the holomorphic solutions is done using the power series method and using the q-Briot-Bouquet theorem A.1 to prove convergence. Ohyama [18,19] classified the meromorphic solutions of the discrete Painlevé equations q-P VI , q-P V and q-P III around the origin in this fashion. As the q-P(A 1 ) case is quite similar, we keep our discussion brief.…”

“…Moreover, Grammaticos et al's studies of singularity confinement and special solutions could be described as analytic information about solutions. Ohyama [18,19] studied analytic properties of q-Painlevé equations, classified all analytic solutions to the equations q-P VI , q-P V and q-P III around the origin and solved the associated linear connection problems. Mano [16], building on Ohyama's results, derived solutions to the equation q-P VI described by a broad range of asymptotics near the origin and likewise near infinity.…”

Analytic solutions ofq-P(A₁) near its critical points

“…Classifying the holomorphic solutions is done using the power series method and using the q-Briot-Bouquet theorem A.1 to prove convergence. Ohyama [18,19] classified the meromorphic solutions of the discrete Painlevé equations q-P VI , q-P V and q-P III around the origin in this fashion. As the q-P(A 1 ) case is quite similar, we keep our discussion brief.…”

“…Moreover, Grammaticos et al's studies of singularity confinement and special solutions could be described as analytic information about solutions. Ohyama [18,19] studied analytic properties of q-Painlevé equations, classified all analytic solutions to the equations q-P VI , q-P V and q-P III around the origin and solved the associated linear connection problems. Mano [16], building on Ohyama's results, derived solutions to the equation q-P VI described by a broad range of asymptotics near the origin and likewise near infinity.…”

Analytic solutions ofq-P(A₁) near its critical points

“…along the same halflines L γ p as in (5) where the Borel map Θ p ðu, zÞ remains holomorphic w.r.t z on D but suffers now (at most) exponential growth rate (91) of order k relatively to u on U p (and not in general q − exponential increase as it was the case for w p ). The second item is achieved in Subsection 4.5 (Theorem 30) where the existence of a formal power series vðt, zÞ = ∑ l≥0 h l ðzÞt l , with holomorphic coefficients h l ðzÞ on D, is established which stands for the common Gevrey asymptotic expansion of mixed order ð1/k ; ðq, 1ÞÞ on T p of the partial maps t ↦ v p ðt, zÞ, 0 ≤ p ≤ ς − 1, satisfying therefore similar estimates to (6).…”

“…Regarding the existence of local holomorphic solutions to nonlinear q − difference equations, we may refer to some recent works. Indeed, for meromorphic or holomorphic solutions around the origin for special type of nonlinear q − difference equations such as the q − Painlevé equations, we can mention [5,6]. Some category of nonlinear q − difference equations of the form…”

Asymptotics and Confluence for a Singular Nonlinear $q$-Difference-Differential Cauchy Problem

“…In contrast to the classical Painlevé equations, very few asymptotic investigations have been carried out into discrete versions of the Painlevé equations, classified by Sakai [31]. Three such studies are currently known: the additive difference first Painlevé equation [14], the q-discrete sixth Painlevé equation [20], and the q-discrete first Painlevé equation (qP I ) [23,16]. Nishioka [22] showed that qP I , which has initial value space A…”

An Overview of Geometric Asymptotic Analysis of Continuous and Discrete Painlevé Equations