The Canny–Emiris Conjecture for the Sparse Resultant

DʼAndrea, Carlos; Jeronimo, Gabriela; Sombra, Martín

doi:10.1007/s10208-021-09547-3

Cited by 3 publications

(1 citation statement)

References 33 publications

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“…Since perfograms represent sub-resultants, each initial form is given by a collection of perfograms [21,29]: Definition 4.3 Initial form init φ , supported on the face φ of N (R), is the product of certain sub-resultants R kι ι times a monomial µ φ :…”

Section: The Main Conjecture and Sketch Of The Proofmentioning

confidence: 99%

Combinatorics of Nahm sums, quiver resultants and the K-theoretic condition

Noshchenko

2020

Preprint

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Algebraic Nahm equations, considered in the paper, are polynomial equations, governing the q → 1 limit of the q-hypergeometric Nahm sums. They make an appearance in various fields: hyperbolic geometry, knot theory, quiver representation theory, topological strings and conformal field theory. In this paper we focus primarily on Nahm sums and Nahm equations that arise in relation with quivers. For a large class of symmetric quivers, we prove that quiver A-polynomials, that is, specialized resultants of the Nahm equations, are tempered (the so-called K-theoretic condition). This implies that they are quantizable. Moreover, we find that their face polynomials obey a remarkable combinatorial pattern, reminiscent of the permutohedron. We use the machinery of initial forms and mixed polyhedral decompositions to investigate the edges of the Newton polytope. We work out all diagonal quivers with adjacency matrix C = diag(α, α, . . . , α), α ≥ 2, and give a sketch when the diagonal entries are all distinct. We also conjecture that it holds for all symmetric quivers.

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Section: The Main Conjecture and Sketch Of The Proofmentioning

confidence: 99%

Combinatorics of Nahm sums, quiver resultants and the K-theoretic condition

Noshchenko

2020

Preprint

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Mixed Subdivisions Suitable for the Greedy Canny–Emiris Formula

Checa,

Emiris

2024

Math.Comput.Sci.

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The Canny–Emiris formula (Canny and Emiris in International symposium on applied algebra, algebraic algorithms, and error-correcting codes, 1993) gives the sparse resultant as the ratio of the determinant of a Sylvester-type matrix over a minor of it, both obtained via a mixed subdivision algorithm. In Checa and Emiris (Proceedings of the 2022 international symposium on symbolic and algebraic computation, 2022), the same authors gave an explicit class of mixed subdivisions for the greedy approach so that the formula holds, and the dimension of the constructed matrices is smaller than that of the subdivision algorithm, following the approach of Canny and Pedersen (An algorithm for the Newton resultant, 1993). Our method improves upon the dimensions of the matrices when the Newton polytopes are zonotopes and the systems are multihomogeneous. In this text, we provide more such cases, and we conjecture which might be the liftings providing minimal size of the resultant matrices. We also describe two applications of this formula, namely in computer vision and in the implicitization of surfaces, while offering the corresponding JULIA code. We finally introduce a novel tropical approach that leads to an alternative proof of a result in Checa and Emiris (Proceedings of the 2022 international symposium on symbolic and algebraic computation, 2022).

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Toric Sylvester forms

Busé,

Checa

2024

Journal of Pure and Applied Algebra

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The Canny–Emiris Conjecture for the Sparse Resultant

Cited by 3 publications

References 33 publications

Combinatorics of Nahm sums, quiver resultants and the K-theoretic condition

Combinatorics of Nahm sums, quiver resultants and the K-theoretic condition

Mixed Subdivisions Suitable for the Greedy Canny–Emiris Formula

Toric Sylvester forms

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