The arrangement of network nodes in hyperbolic spaces has become a widely studied problem, motivated by numerous results suggesting the existence of hidden metric spaces behind the structure of complex networks. Although several methods have already been developed for the hyperbolic embedding of undirected networks, approaches able to deal with directed networks are still in their infancy. Here, we propose a framework based on the dimension reduction of proximity matrices reflecting the network topology, coupled with a general conversion method transforming Euclidean node coordinates into hyperbolic ones even for directed networks. While proposing a new measure of proximity, we also incorporate an earlier Euclidean embedding method in our p...
We introduce Mercator, a reliable embedding method to map real complex networks into their hyperbo...
We introduce L-hydra (landmarked hyperbolic distance recovery and approximation), a method for embed...
Hyperbolic geometry appears to be intrinsic in many large real networks. We construct and implement ...
The arrangement of network nodes in hyperbolic spaces has become a widely studied problem, motivated...
One of the pillars of the geometric approach to networks has been the development of model-based map...
Network embedding is a frontier topic in current network science. The scale-free property of complex...
peer-reviewedWe show that the community structure of a network can be used as a coarse version of it...
Abstract One of the pillars of the geometric approach to networks has been the development of model-...
Network science is driven by the question which properties large real-world networks have and how we...
Due to its geometric properties, hyperbolic space can support high-fidelity embeddings of tree- and ...
Heterogeneous information network (HIN) embedding, aiming to project HIN into a low-dimensional spac...
Over the last decade, random hyperbolic graphs have proved successful in providing geometric explana...
Reducing dimension redundancy to find simplifying patterns in high-dimensional datasets and complex ...
Force-directed drawing algorithms are the most commonly used approach to visualize networks. While t...
Force-directed drawing algorithms are the most commonly used approach to visualize networks. While t...
We introduce Mercator, a reliable embedding method to map real complex networks into their hyperbo...
We introduce L-hydra (landmarked hyperbolic distance recovery and approximation), a method for embed...
Hyperbolic geometry appears to be intrinsic in many large real networks. We construct and implement ...
The arrangement of network nodes in hyperbolic spaces has become a widely studied problem, motivated...
One of the pillars of the geometric approach to networks has been the development of model-based map...
Network embedding is a frontier topic in current network science. The scale-free property of complex...
peer-reviewedWe show that the community structure of a network can be used as a coarse version of it...
Abstract One of the pillars of the geometric approach to networks has been the development of model-...
Network science is driven by the question which properties large real-world networks have and how we...
Due to its geometric properties, hyperbolic space can support high-fidelity embeddings of tree- and ...
Heterogeneous information network (HIN) embedding, aiming to project HIN into a low-dimensional spac...
Over the last decade, random hyperbolic graphs have proved successful in providing geometric explana...
Reducing dimension redundancy to find simplifying patterns in high-dimensional datasets and complex ...
Force-directed drawing algorithms are the most commonly used approach to visualize networks. While t...
Force-directed drawing algorithms are the most commonly used approach to visualize networks. While t...
We introduce Mercator, a reliable embedding method to map real complex networks into their hyperbo...
We introduce L-hydra (landmarked hyperbolic distance recovery and approximation), a method for embed...
Hyperbolic geometry appears to be intrinsic in many large real networks. We construct and implement ...