Extending the Toda lattice: spectral function expansions and symplectic maps in higher-dimensional integrable systems

Abstract

This paper presents a unified framework that combines spectral function expansions with symplectic transformations to extend the classical Toda lattice into higher-dimensional integrable systems. Polynomial expansions of the spectral function are used to construct conserved quantities and soliton solutions associated with generalized Lax operators. Spectral methods are then coupled with symplectic maps that preserve the Hamiltonian structure, enabling the embedding of the Toda lattice into higher-dimensional graphs while maintaining integrability. The transition from spectral data to soliton solutions is formalized through Riemann theta functions, revealing the quasi-periodic structure of extended Toda systems. The resulting framework preserves spectral invariants under symplectic transformations, extends results to the construction of higher-dimensional phase spaces, and leads to the emergence of quasi-integrability under both dynamic and stochastic perturbations. These results provide a geometric and algebraic foundation for the study of multidimensional soliton dynamics, integrable systems on graphs, and generalized Hamiltonian flows.