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| Natura: | Preprint |
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2015
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| Accesso online: | https://arxiv.org/abs/1512.05688 |
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| _version_ | 1866917766511984640 |
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| author | Hilany, Boulos El |
| author_facet | Hilany, Boulos El |
| contents | We consider real polynomial systems $f=g=0$ in two variables where $f$ has $t\geq 3$ monomial terms and $g$ has $3$ monomials terms. We prove that the number of positive isolated solutions of such a system does not exceed $3\cdot 2^{t-2} - 1$. This improves the bound $2^t - 2$ obtained in [T.-Y. Li, J.-M. Rojas and X. Wang, 2003]. This also refines for $t=4,\ldots,9$ the bound $2t^3/3 + 5t$ obtained in [P. Koiran, N. Portier and S. Tavenas, 2015]. Our proof is based on a delicate analysis of the Groethendieck's dessin d'enfant associated to some rational function determined by the system. For $t=3$, it was shown in [T.-Y. Li, J.-M. Rojas and X. Wang, 2003] that the sharp bound is five, and if this bound is reached, then the Minkowski sum of the associated Newton triangles is an hexagon. A further analysis of Groethendieck's dessin d'enfant allows us to show that if the bound five is reached, then there exist two consecutive edges of the hexagon which are translate of two consecutive edges of one Newton triangle. |
| format | Preprint |
| id |
arxiv_https___arxiv_org_abs_1512_05688 |
| institution | arXiv |
| publishDate | 2015 |
| record_format | arxiv |
| spellingShingle | Counting positive intersection points of a trinomial and a $\mathbf{T}$-nomial curves via Groethendieck's dessin d'enfant Hilany, Boulos El Algebraic Geometry We consider real polynomial systems $f=g=0$ in two variables where $f$ has $t\geq 3$ monomial terms and $g$ has $3$ monomials terms. We prove that the number of positive isolated solutions of such a system does not exceed $3\cdot 2^{t-2} - 1$. This improves the bound $2^t - 2$ obtained in [T.-Y. Li, J.-M. Rojas and X. Wang, 2003]. This also refines for $t=4,\ldots,9$ the bound $2t^3/3 + 5t$ obtained in [P. Koiran, N. Portier and S. Tavenas, 2015]. Our proof is based on a delicate analysis of the Groethendieck's dessin d'enfant associated to some rational function determined by the system. For $t=3$, it was shown in [T.-Y. Li, J.-M. Rojas and X. Wang, 2003] that the sharp bound is five, and if this bound is reached, then the Minkowski sum of the associated Newton triangles is an hexagon. A further analysis of Groethendieck's dessin d'enfant allows us to show that if the bound five is reached, then there exist two consecutive edges of the hexagon which are translate of two consecutive edges of one Newton triangle. |
| title | Counting positive intersection points of a trinomial and a $\mathbf{T}$-nomial curves via Groethendieck's dessin d'enfant |
| topic | Algebraic Geometry |
| url | https://arxiv.org/abs/1512.05688 |