The project has six precise tasks, T1.1-T1.4 and T2.1-T2.2 which have been approached during the 72 months of the project.
T1.1 Study degenerate Bautin bifurcations. Results have been obtained on this topic in the first part of the project, when a normal form which involves the third Lyapunov coefficient and a method for determining the coefficient have been obtained.
T1.2 Study degenerate Hopf-Hopf bifurcation. We approached this bifurcation, known also as double-Hopf, in a degenerate context given by the elimination of one generic condition at once used for determining a normal form in the non-degenerate case. Six such degenerate cases have been studied and the results are published in three papers [1]-[3].
T1.3 Study other codimension k bifurcations in continuous (smooth) systems. We have studied: a model for the tuberculosis and the Dengue fever [4], a system related to the two-body problem [5], a finance model [6], a dynamical system with an equilibrium having two zero eigenvalues [7], the birth and death of families of algebraic limit cycles of quadratic polynomial differential systems (pde) [8], the criticality of some planar systems of pde having a center for various low degrees n [9], the phase portraits of a 3-dimensional Lotka–Volterra system for all the values of two parameters [10], the dynamics of a 3-dimensional Muthuswamy-Chua system in the infinity of the Poincare ball for all values of the parameter [11].
T1.4 Study other codim k bifurcations in discrete systems. Related to this task we have studied: degenerate Chenciner bifurcation [27]-[29], the fixed points of a return map [30], continuous self-maps on topological graphs [31], the set of periods of the Morse–Smale diffeomorphisms in several cases [32].
T2.1 Study codim k bifurcations in non-smooth systems. We have studied: discontinuous planar piecewise differential systems (pds) formed by linear centers and separated by two concentric circles [33], the number of limit cycles of planar pds separated by a branch of an algebraic curves [34], discontinuous pds formed by two linear centers separated by a nonregular straight line [35], the conjecture of Markus and Yamabe to continuous and discontinuous pds [36].
T2.2 Study bifurcations in non-smooth systems with impacts and applications of mathematics and other disciplines in the medical field.
We have studied: a mathematical model for the interactions between human immune system and a pathogenic virus, such as Covid-19 [41], several aspects in computer-assisted surgery [42], a SIR system [43], a SEIR model [44], a predator–prey system [45], two NZP models [46], a model for cancerous tumors [47] and [48].
As an overview, the project main results are in dynamical systems theory and its applications, where they can be exploited. The results are disseminated as green or gold open access articles.
[1] G. Tigan, 2021a.
[2]-[3] G. Moza, 2022a, 2022b.
[4]-[5] J. Llibre, 2019, 2018.
[6] M.R. Candido, 2018.
[7] C. Rocsoreanu, 2019.
[8] J. Llibre, 2021a.
[9] I. Sánchez-Sánchez, 2021a.
[10] J. Llibre, 2020a.
[11] Y. P. Martínez, 2024.
[12]-[13] J. Llibre, 2022, 2021b.
[14] R. Oliveira, 2022.
[15] I. Sánchez-Sánchez, 2021b.
[16] C. A. Buzzi, 2021.
[17] G. Moza, 2022c.
[18] J. Itikawa, 2022.
[19] I. Sánchez-Sánchez, 2022.
[20] M. Boureanu, 2022.
[21] E. Musafirov, 2022.
[22] C-P. Danet, 2022.
[23] C. Ionescu, 2022.
[24]-[25] G. Moza, 2023a, 2024.
[26] J. Llibre, 2023.
[27]-[28] G. Tigan, 2020, 2021b.
[29] S. Lugojan, 2022.
[30]-[31] J. Llibre, 2020b, 2021c.
[32] C. Cufi-Cabre, 2022.
[33] M.E. Anacleto, 2021.
[34] A. Gasull, 2020.
[35] M. Esteban, 2021.
[36] J. Llibre, 2021d.
[37] E. Freire, 2021.
[38] X. Chen, 2022.
[39] L. P. C. da Cruz, 2022.
[40] M. E. Anacleto, 2023.
[41] G. Moza, 2023b.
[42] J. Ehrlich, 2022.
[43] D. Constantinescu, 2022.
[44] L. Bucur, 2022.
[45] F. Munteanu, 2022.
[46] M. Sterpu, 2023.
[47] D. A. Drexler, 2024.
[48] L. Kovács, 2024.