Pauline Sarrabezolles scite author profile

Pauline Sarrabezolles

4Publications

43Citation Statements Received

89Citation Statements Given

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Affiliations

Center for Training and Research in MathematIcs and Scientific Computing, Université Paris Cité, École des Ponts ParisTech

Publications

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The Rainbow at the End of the Line — A PPAD Formulation of the Colorful Carathéodory Theorem with Applications

Meunier¹,

Mulzer²,

Sarrabezolles³

et al. 2017

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Let C 1 , ..., C d+1 be d + 1 point sets in R d , each containing the origin in its convex hull. A subset C of d+1 i=1 C i is called a colorful choice (or rainbow) for C 1 , . . . , C d+1 , if it contains exactly one point from each set C i . The colorful Carathéodory theorem states that there always exists a colorful choice for C 1 , . . . , C d+1 that has the origin in its convex hull. This theorem is very general and can be used to prove several other existence theorems in high-dimensional discrete geometry, such as the centerpoint theorem or Tverberg's theorem. The colorful Carathéodory problem (ColorfulCarathéodory) is the computational problem of finding such a colorful choice. Despite several efforts in the past, the computational complexity of ColorfulCarathéodory in arbitrary dimension is still open.We show that ColorfulCarathéodory lies in the intersection of the complexity classes PPAD and PLS. This makes it one of the few geometric problems in PPAD and PLS that are not known to be solvable in polynomial time. Moreover, it implies that the problem of computing centerpoints, computing Tverberg partitions, and computing points with large simplicial depth is contained in PPAD ∩ PLS. This is the first nontrivial upper bound on the complexity of these problems.Finally, we show that our PPAD formulation leads to a polynomial-time algorithm for a special case of ColorfulCarathéodory in which we have only two color classes C 1 and C 2 in d dimensions, each with the origin in its convex hull, and we would like to find a set with half the points from each color class that contains the origin in its convex hull.

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The unimodular intersection problem

Kaibel

Onn

Sarrabezolles

2015

Operations Research Letters

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Huge Unimodular $n$-Fold Programs

Onn¹,

Sarrabezolles²

2015

SIAM J. Discrete Math.

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Optimization over l × m × n integer 3-way tables with given line-sums is NP-hard already for fixed l = 3, but is polynomial time solvable with both l, m fixed. In the huge version of the problem, the variable dimension n is encoded in binary, with t layer types. It was recently shown that the huge problem can be solved in polynomial time for fixed t, and the complexity of the problem for variable t was raised as an open problem. Here we solve this problem and show that the huge table problem can be solved in polynomial time even when the number t of types is variable. The complexity of the problem over 4-way tables with variable t remains open. Our treatment goes through the more general class of huge n-fold integer programming problems. We show that huge integer programs over n-fold products of totally unimodular matrices can be solved in polynomial time even when the number t of brick types is variable.

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The colourful simplicial depth conjecture

Sarrabezolles

2015

Journal of Combinatorial Theory, Series A

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Given d + 1 sets of points, or colours, S 1 , . . . ,The colourful Carathéodory theorem states that, if 0 is in the convex hull of each S i , then there exists a colourful simplex T containing 0 in its convex hull. Deza, Huang, Stephen, and Terlaky (Colourful simplicial depth, Discrete Comput. Geom., 35, 597-604 (2006)) conjectured that, when |S i | = d + 1 for all i ∈ {1, . . . , d + 1}, there are always at least d 2 + 1 colourful simplices containing 0 in their convex hulls. We prove this conjecture via a combinatorial approach.

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