Abelian versus non-Abelian Baecklund Charts: some remarks

Connections via Baecklund transformations among different non-linear evolution equations are investigated aiming to compare corresponding Abelian and non Abelian results. Specifically, links, via Baecklund transformations, connecting Burgers and KdV-type hierarchies of nonlinear evolution equations are studied. Crucial differences as well as notable similarities between Baecklund charts in the case of the Burgers - heat equation, on one side and KdV -type equations are considered. The Baecklund charts constructed in [16] and [17], respectively, to connect Burgers and KdV-type hierarchies of operator nonlinear evolution equations show that the structures, in the non-commutative cases, are richer than the corresponding commutative ones.Comment: 18 page

Construction of soliton solutions of the matrix modified Korteweg-de Vries equation

An explicit solution formula for the matrix modified KdV equation is presented, which comprises the solutions given in Ref. 7 (S. Carillo, M. Lo Schiavo, and C. Schiebold. Matrix solitons solutions of the modified Korteweg-de Vries equation. In: Nonlinear Dynamics of Structures, Systems and Devices, edited by W. Lacarbonara, B. Balachandran, J. Ma, J. Tenreiro Machado, G. Stepan (Springer, Cham, 2020), pp. 75-83). In fact, the solutions in Ref.7 are part of a subclass studied in detail by the authors in a forthcoming publication. Here several solutions beyond this subclass are constructed and discussed with respect to qualitative properties.Comment: 10 pages, 6 figures, Proceedings of the Second International Nonlinear Dynamics Conference (NODYCON 2021), W. Lacarbonara et al, Ed.

Soliton equations: admitted solutions and invariances via Bäcklund transformations

A couple of applications of Baecklund transformations in the study of nonlinear evolution equations is here given. Specifically, we are concerned about third order nonlinear evolution equations. Our attention is focussed on one side, on proving a new invariance admitted by a third order nonlinear evolution equation and, on the other one, on the construction of solutions. Indeed, via B ̈acklund transformations, a Baecklund chart, connecting Abelian as well as non Abelian equations can be constructed. The importance of such a net of links is twofold since it indicates invariances as well as allows to construct solutions admitted by the nonlinear evolution equations it relates. The present study refers to third-order nonlinear evolution equations of KdV type. On the basis of the Abelian wide Baecklund chart which connects various different third order nonlinear evolution equations an invariance admitted by the Korteweg-deVries interacting soliton (int.sol.KdV) equation is obtained and a related new explicit solution is constructed. Then, the corresponding non-Abelian Baecklund chart, shows how to construct matrix solutions of the mKdV equations: some recently obtained solutions are reconsidered

Construction of soliton solutions of the matrix modified Korteweg-de Vries equation

An explicit solution formula for the matrix modified KdV equation is presented, which comprises the solutions given in [ S. Carillo, M. Lo Schiavo, and C. Schiebold. Matrix solitons solutions of the modified Korteweg-de Vries equation. In: Nonlinear Dynamics of Structures, Systems and Devices, edited by W. Lacarbonara, B. Balachandran, J. Ma, J. Tenreiro Machado, G. Stepan. (Springer, Cham, 2020), pp. 75–83]. In fact, the solutions therein are part of a subclass studied in detail by the authorsin a forthcoming publication. Here several solutions beyond this subclass are constructed and discussed with respect to qualitative properties

Soliton equations: admitted solutions and invariances via B\"acklund transformations

A couple of applications of B\"acklund transformations in the study of nonlinear evolution equations is here given. Specifically, we are concerned about third order nonlinear evolution equations. Our attention is focussed on one side, on an invariance admitted by the interacting soliton equation and, on the other one, on the construction of solutions. Indeed, via B\"acklund transformations, a B\"acklund chart, connecting Abelian as well as non Abelian equations can be constructed. The importance of such a net of links is twofold since it indicates invariances as well as allows to construct solutions admitted by the nonlinear evolution equations it relates. The present study refers to third order nonlinear evolution equations of KdV type. On the basis of the Abelian wide B\"acklund chart which connects various different third order nonlinear evolution equations an invariance admitted by the int sol. KdV equation is obtained and an explicit solution is constructed. Then, the corresponding non-Abelian B\"acklund chart, shows how to construct matrix solutions of the mKdV equations: some recently obtained solutions are reconsidered.Comment: 11 pages, 6 figures. arXiv admin note: text overlap with arXiv:2101.0924

A novel noncommutative KdV-type equation, its recursion operator, and solitons

A noncommutative KdV-type equation is introduced extending the Baecklund chart in [S. Carillo, M. Lo Schiavo, and C. Schiebold, SIGMA 12 (2016)]. This equation, called meta-mKdV here, is linked by Cole-Hopf transformations to the two noncommutative versions of the mKdV equations listed in [P.J. Olver and V.V. Sokolov Commun. Math. Phys. 193 (1998), Theorem 3.6]. For this meta-mKdV, and its mirror counterpart, recursion operators, hierarchies and an explicit solution class are derived

The noncommutative AKNS system: projection to matrix systems, countable superposition and soliton-like solutions

Starting from the recent work on noncommutative AKNS systems for functions with values in the bounded operators on a Banach space, it is shown how their formal 1-soliton solution (depending on operator parameters) can be mapped to solutions of matrix AKNS systems. The main result is rather general solution formulas for matrix AKNS systems. The most important applications are the countable superposition of matrix solitons and explicit expressions for the soliton-like solutions of the classical AKNS system.</p