On real and imaginary roots of generalised Okamoto polynomials

Abstract

Recently, B. Yang and J. Yang derived a family of rational solutions to the Sasa-Satsuma equation, and showed that any of its members constitutes a partial-rogue wave provided that an associated generalised Okamoto polynomial has no real roots or no imaginary roots. In this paper, we derive exact formulas for the number of real and the number of imaginary roots of the generalised Okamoto polynomials. On the one hand, this yields a list of partial-rogue waves that satisfy the Sasa-Satsuma equation. On the other hand, it gives families of rational solutions of the fourth Painlevé equation that are pole-free on either the real line or the imaginary line. To obtain these formulas, we develop an algorithmic procedure to derive the qualitative distribution of singularities on the real line for real solutions of Painlevé equations, starting from the known distribution for a seed solution, through the action of Bäcklund transformations on the rational surfaces forming their spaces of initial conditions.

Figures (14)

• Figure 1: Plots of some generalised Okamoto rationals $q_{m,n}(t)$
• Figure 2: Regions in the $(m,n)$-plane
• Figure 3: Number of real roots of $Q_{m,n}$ in the $(m,n)$-plane, for $-7\leq m,n\leq 7$, as well as curves (in green) along which real roots are interlaced as detailed in Corollary \ref{['cor:interlacing']}.
• Figure 4: Plots of some Okamoto rationals which are pole-free on the real line.
• Figure 5: Blow-up points for Okamoto's space for system \ref{['eq:systfg']}

Theorems & Definitions (110)

• Theorem 1.1: Yang and Yang yangyang
• Corollary 1.2
• Definition 2.1: plus or minus zeros and poles
• Remark 2.2
• Lemma 2.3
• Remark 2.4
• Remark 2.5
• Remark 2.6
• Definition 2.7: singularity signatures of real solutions
• Theorem 3.1: Region $\mathrm{I}$