Your search keyword '"Angelini, Patrizio"' showing total 306 results

301. Simultaneous Orthogonal Planarity

Author

Ignaz Rutter, Peter Eades, Steven Chaplick, Fabian Lipp, Giordano Da Lozzo, Patrizio Angelini, Jan Kratochvíl, Philipp Kindermann, Giuseppe Di Battista, Sabine Cornelsen, Yifan Hu and Martin Nöllenburg, Angelini, Patrizio, Chaplick, Steven, Cornelsen, Sabine, Da Lozzo, Giordano, Di Battista, Giuseppe, Eades, Peter, Kindermann, Philipp, Kratochvã­l, Jan, Lipp, Fabian, and Rutter, Ignaz

Subjects

Computational Geometry (cs.CG), FOS: Computer and information sciences, 0102 computer and information sciences, 02 engineering and technology, 01 natural sciences, Biconnected graph, Theoretical Computer Science, Combinatorics, symbols.namesake, Outerplanar graph, Computer Science - Data Structures and Algorithms, 0202 electrical engineering, electronic engineering, information engineering, Data Structures and Algorithms (cs.DS), Complement graph, Mathematics, Discrete mathematics, Block graph, Degree (graph theory), Computer Science (all), Planar graph, 010201 computation theory & mathematics, symbols, Computer Science - Computational Geometry, 020201 artificial intelligence & image processing, Regular graph, Path graph

Abstract

We introduce and study the $\textit{OrthoSEFE}-k$ problem: Given $k$ planar graphs each with maximum degree 4 and the same vertex set, do they admit an OrthoSEFE, that is, is there an assignment of the vertices to grid points and of the edges to paths on the grid such that the same edges in distinct graphs are assigned the same path and such that the assignment induces a planar orthogonal drawing of each of the $k$ graphs? We show that the problem is NP-complete for $k \geq 3$ even if the shared graph is a Hamiltonian cycle and has sunflower intersection and for $k \geq 2$ even if the shared graph consists of a cycle and of isolated vertices. Whereas the problem is polynomial-time solvable for $k=2$ when the union graph has maximum degree five and the shared graph is biconnected. Further, when the shared graph is biconnected and has sunflower intersection, we show that every positive instance has an OrthoSEFE with at most three bends per edge., Comment: Appears in the Proceedings of the 24th International Symposium on Graph Drawing and Network Visualization (GD 2016)

302. The importance of being proper: (In clustered-level planarity and T-level planarity)

Author

Fabrizio Frati, Giordano Da Lozzo, Giuseppe Di Battista, Vincenzo Roselli, Patrizio Angelini, Christian Duncan, Antonios Symvonis, Angelini, Patrizio, DA LOZZO, Giordano, DI BATTISTA, Giuseppe, Frati, Fabrizio, and Roselli, Vincenzo

Subjects

Discrete mathematics, Combinatorics, Planarity testing, Mathematics

Abstract

In this paper we study two problems related to the drawing of level graphs, that is, T -Level Planarity and Clustered-Level Planarity. We show that both problems are $\mathcal{NP}$ -complete in the general case and that they become polynomial-time solvable when restricted to proper instances.

303. Morphing planar graph drawings with a polynomial number of steps

Author

Soroush Alamdari, Patrizio Angelini, Timothy M. Chan, Giuseppe Di Battista, Fabrizio Frati, Anna Lubiw, Maurizio Patrignani, Vincenzo Roselli, Sahil Singla, Bryan T. Wilkinson, Sanjeev Khanna, Soroush, Alamdari, Angelini, Patrizio, Timothy M., Chan, DI BATTISTA, Giuseppe, Frati, Fabrizio, Anna, Lubiw, Patrignani, Maurizio, Roselli, Vincenzo, Sahil, Singla, and Bryan T., Wilkinson

Subjects

Computer Science::Graphics, Computer Science::Computational Geometry, ComputingMethodologies_COMPUTERGRAPHICS, MathematicsofComputing_DISCRETEMATHEMATICS

Abstract

In 1944, Cairns proved the following theorem: given any two straight-line planar drawings of a triangulation with the same outer face, there exists a morph (i.e., a continuous transformation) between the two drawings so that the drawing remains straight-line planar at all times. Cairns’s original proof required exponentially many morphing steps. We prove that there is a morph that consists of O(n^2) steps, where each step is a linear morph that moves each vertex at constant speed along a straight line. Using a known result on compatible triangulations this implies that for a general planar graph G and any two straight-line planar drawings of G with the same embedding, there is a morph between the two drawings that preserves straight-line planarity and consists of O(n^4) steps.

304. Testing planarity of partially embedded graphs

Author

Patrizio Angelini, Maurizio Patrignani, Jan Kratochvíl, Fabrizio Frati, Giuseppe Di Battista, Vít Jelínek, Ignaz Rutter, Angelini, Patrizio, DI BATTISTA, Giuseppe, Frati, Fabrizio, Jelinek, Vit, Kratochvil, Jan, Patrignani, Maurizio, Rutter, Ignaz, Moses Charikar, Angelini, P, Jelinek, V, Kratochvil, J, and Rutter, I.

Subjects

Discrete mathematics, Book embedding, Planar straight-line graph, Graph embedding, Planarity testing, Planar graph, Modular decomposition, Combinatorics, symbols.namesake, Mathematics (miscellaneous), Outerplanar graph, symbols, Topological graph theory, planarity, embedding extension, triconnected graphs, Mathematics, MathematicsofComputing_DISCRETEMATHEMATICS

Abstract

We study the following problem: given a planar graph G and a planar drawing (embedding) of a subgraph of G , can such a drawing be extended to a planar drawing of the entire graph G ? This problem fits the paradigm of extending a partial solution for a problem to a complete one, which has been studied before in many different settings. Unlike many cases, in which the presence of a partial solution in the input makes an otherwise easy problem hard, we show that the planarity question remains polynomial-time solvable. Our algorithm is based on several combinatorial lemmas, which show that the planarity of partially embedded graphs exhibits the ‘TONCAS’ behavior “the obvious necessary conditions for planarity are also sufficient.” These conditions are expressed in terms of the interplay between (1) the rotation system and containment relationships between cycles and (2) the decomposition of a graph into its connected, biconnected, and triconnected components. This implies that no dynamic programming is needed for a decision algorithm and that the elements of the decomposition can be processed independently. Further, by equipping the components of the decomposition with suitable data structures and by carefully splitting the problem into simpler subproblems, we make our algorithm run in linear time. Finally, we consider several generalizations of the problem, such as minimizing the number of edges of the partial embedding that need to be rerouted to extend it, and argue that they are NP-hard. We also apply our algorithm to the simultaneous graph drawing problem Simultaneous Embedding with Fixed Edges (Sefe) . There we obtain a linear-time algorithm for the case that one of the input graphs or the common graph has a fixed planar embedding.

305. BGPlay3D: Exploiting the ribbon representation to show the evolution of interdomain routing

Author

Angelini, P., Clarucci, L. A., Candela, M., Patrignani, M., Massimo Rimondini, Sepe, R., Stephen Wismath, Alexander Wolff, Angelini, Patrizio, Lorenzo ANTONETTI, Clarucci, Massimo, Candela, Patrignani, Maurizio, Rimondini, Massimo, and Roberto, Sepe

306. Splitting Vertices in 2-Layer Graph Drawings.

Author

Ahmed R, Angelini P, Bekos MA, Battista GD, Kaufmann M, Kindermann P, Kobourov S, Nollenburg M, Symvonis A, Villedieu A, and Wallinger M

Abstract

Bipartite graphs model the relationships between two disjoint sets of entities in several applications and are naturally drawn as 2-layer graph drawings. In such drawings, the two sets of entities (vertices) are placed on two parallel lines (layers), and their relationships (edges) are represented by segments connecting vertices. Methods for constructing 2-layer drawings often try to minimize the number of edge crossings. We use vertex splitting to reduce the number of crossings, by replacing selected vertices on one layer by two (or more) copies and suitably distributing their incident edges among these copies. We study several optimization problems related to vertex splitting, either minimizing the number of crossings or removing all crossings with fewest splits. While we prove that some variants are ${\mathsf {NP}}$NP-complete, we obtain polynomial-time algorithms for others. We run our algorithms on a benchmark set of bipartite graphs representing the relationships between human anatomical structures and cell types.

Published

2023