Your search keyword '"Ilkka Kivimäki"' showing total 6 results

1. Accelerating advances in landscape connectivity modelling with the ConScape library

Author

Bram Van Moorter, Ilkka Kivimäki, Andreas Noack, Robin Devooght, Manuela Panzacchi, Kimberly R. Hall, Pierre Leleux, and Marco Saerens

Subjects

circuitscape, conefor, ecological networks, least‐cost path, metapopulation, random walk, Ecology, QH540-549.5, Evolution, QH359-425

Abstract

Abstract Increasingly precise spatial data (e.g. high‐resolution imagery from remote sensing) allow for improved representations of the landscape network for assessing the combined effects of habitat loss and connectivity declines on biodiversity. However, evaluating large landscape networks presents a major computational challenge both in terms of working memory and computation time. We present the ConScape (i.e. “connected landscapes”) software library implemented in the high‐performance open‐source Julia language to compute metrics for connected habitat and movement flow on high‐resolution landscapes. The combination of Julia's ‘just‐in‐time’ compiler, efficient algorithms and ‘landmarks’ to reduce the computational load allows ConScape to compute landscape ecological metrics—originally developed in metapopulation ecology (such as ‘metapopulation capacity’ and ‘probability of connectivity’)—for large landscapes. An additional major innovation in ConScape is the adoption of the randomized shortest paths framework to represent connectivity along the continuum from optimal to random movements, instead of only those extremes. We demonstrate ConScape's potential for using large datasets in sustainable land planning by modelling landscape connectivity based on remote‐sensing data paired with GPS tracking of wild reindeer in Norway. To guide users, we discuss other applications, and provide a series of worked examples to showcase all ConScape's functionalities in Supplementary Material. Built by a team of ecologists, network scientists and software developers, ConScape is able to efficiently compute landscape metrics for high‐resolution landscape representations to leverage the availability of large data for sustainable land use and biodiversity conservation. As a Julia implementation, ConScape combines computational efficiency with a transparent code base, which facilitates continued innovation through contributions from the rapidly growing community of landscape and connectivity modellers using Julia.

Published

2023

2. Accelerating advances in landscape connectivity modelling with the ConScape library

Author

Bram Van Moorter, Ilkka Kivimäki, Andreas Noack, Robin Devooght, Manuela Panzacchi, Kimberly R. Hall, Pierre Leleux, and Marco Saerens

Subjects

random walk, Ecological Modeling, least-cost path, metapopulation, ecological networks, randomized shortest paths, Matematikk og Naturvitenskap: 400::Zoologiske og botaniske fag: 480 [VDP], circuitscape, Ecology, Evolution, Behavior and Systematics, conefor

Abstract

Increasingly precise spatial data (e.g. high-resolution imagery from remote sensing) allow for improved representations of the landscape network for assessing the combined effects of habitat loss and connectivity declines on biodiversity. However, evaluating large landscape networks presents a major computational challenge both in terms of working memory and computation time. We present the ConScape (i.e. “connected landscapes”) software library implemented in the high-performance open-source Julia language to compute metrics for connected habitat and movement flow on high-resolution landscapes. The combination of Julia's ‘just-in-time’ compiler, efficient algorithms and ‘landmarks’ to reduce the computational load allows ConScape to compute landscape ecological metrics—originally developed in metapopulation ecology (such as ‘metapopulation capacity’ and ‘probability of connectivity’)—for large landscapes. An additional major innovation in ConScape is the adoption of the randomized shortest paths framework to represent connectivity along the continuum from optimal to random movements, instead of only those extremes. We demonstrate ConScape's potential for using large datasets in sustainable land planning by modelling landscape connectivity based on remote-sensing data paired with GPS tracking of wild reindeer in Norway. To guide users, we discuss other applications, and provide a series of worked examples to showcase all ConScape's functionalities in Supplementary Material. Built by a team of ecologists, network scientists and software developers, ConScape is able to efficiently compute landscape metrics for high-resolution landscape representations to leverage the availability of large data for sustainable land use and biodiversity conservation. As a Julia implementation, ConScape combines computational efficiency with a transparent code base, which facilitates continued innovation through contributions from the rapidly growing community of landscape and connectivity modellers using Julia. circuitscape, conefor, ecological networks, least-cost path, metapopulation, random walk, randomized shortest paths

Published

2022

3. Maximum likelihood estimation for randomized shortest paths with trajectory data

Author

Ilkka Kivimäki, Marco Saerens, Jari Saramäki, Manuela Panzacchi, and Bram Van Moorter

Subjects

FOS: Computer and information sciences, shortest path, Control and Optimization, Computer Networks and Communications, Computer science, Maximum likelihood, 010103 numerical & computational mathematics, 02 engineering and technology, Management Science and Operations Research, 01 natural sciences, Statistics - Computation, random walk, Computer Science - Data Structures and Algorithms, 0202 electrical engineering, electronic engineering, information engineering, Data Structures and Algorithms (cs.DS), 0101 mathematics, maximum likelihood, Computation (stat.CO), Social and Information Networks (cs.SI), Applied Mathematics, Computer Science - Social and Information Networks, Computational Mathematics, Trajectory, 020201 artificial intelligence & image processing, randomized shortest paths, animal movement modelling, parameter estimation, Algorithm

Abstract

Randomized shortest paths (RSPs) are tool developed in recent years for different graph and network analysis applications, such as modelling movement or flow in networks. In essence, the RSP framework considers the temperature-dependent Gibbs–Boltzmann distribution over paths in the network. At low temperatures, the distribution focuses solely on the shortest or least-cost paths, while with increasing temperature, the distribution spreads over random walks on the network. Many relevant quantities can be computed conveniently from this distribution, and these often generalize traditional network measures in a sensible way. However, when modelling real phenomena with RSPs, one needs a principled way of estimating the parameters from data. In this work, we develop methods for computing the maximum likelihood estimate of the model parameters, with focus on the temperature parameter, when modelling phenomena based on movement, flow or spreading processes. We test the validity of the derived methods with trajectories generated on artificial networks as well as with real data on the movement of wild reindeer in a geographic landscape, used for estimating the degree of randomness in the movement of the animals. These examples demonstrate the attractiveness of the RSP framework as a generic model to be used in diverse applications. randomized shortest paths; random walk; shortest path; parameter estimation; maximum likelihood; animal movement modelling

Published

2020

4. Two betweenness centrality measures based on Randomized Shortest Paths

Author

Marco Saerens, Ilkka Kivimäki, Bertrand Lebichot, Jari Saramäki, UCL - SSH/ILSM - Louvain School of Management Research Institute, Department of Computer Science, Université catholique de Louvain, Aalto-yliopisto, and Aalto University

Subjects

FOS: Computer and information sciences, Physics - Physics and Society, Theoretical computer science, Current (mathematics), Computer science, FOS: Physical sciences, 02 engineering and technology, Physics and Society (physics.soc-ph), 01 natural sciences, Distance measures, Article, Betweenness centrality, 0103 physical sciences, Computer Science - Data Structures and Algorithms, 0202 electrical engineering, electronic engineering, information engineering, Data Structures and Algorithms (cs.DS), 010306 general physics, ta113, Social and Information Networks (cs.SI), Multidisciplinary, Computer Science - Social and Information Networks, Random walk, Probability distribution, 020201 artificial intelligence & image processing, Centrality, Focus (optics)

Abstract

This paper introduces two new closely related betweenness centrality measures based on the Randomized Shortest Paths (RSP) framework, which fill a gap between traditional network centrality measures based on shortest paths and more recent methods considering random walks or current flows. The framework defines Boltzmann probability distributions over paths of the network which focus on the shortest paths, but also take into account longer paths depending on an inverse temperature parameter. RSP's have previously proven to be useful in defining distance measures on networks. In this work we study their utility in quantifying the importance of the nodes of a network. The proposed RSP betweenness centralities combine, in an optimal way, the ideas of using the shortest and purely random paths for analysing the roles of network nodes, avoiding issues involving these two paradigms. We present the derivations of these measures and how they can be computed in an efficient way. In addition, we show with real world examples the potential of the RSP betweenness centralities in identifying interesting nodes of a network that more traditional methods might fail to notice., Comment: Minor updates; published in Scientific Reports

Published

2015

5. Predicting the continuum between corridors and barriers to animal movements using Step Selection Functions and Randomized Shortest Paths

Author

Bram Van Moorter, Manuela Panzacchi, Colleen Cassady St. Clair, Luigi Boitani, Olav Strand, Marco Saerens, Ilkka Kivimäki, and Ivar Herfindal

Subjects

0106 biological sciences, Mathematical optimization, Computer science, Movement, Models, Biological, 010603 evolutionary biology, 01 natural sciences, Animals, Ecosystem, Ecology, Evolution, Behavior and Systematics, Selection (genetic algorithm), Bottlenecks, Connectivity, Gene flow, Graph theory, Green infrastructures, Obstacles, Permeability, Space use, Tactical and strategic movements, Ecology, Cognitive map, Norway, Continuum (topology), 010604 marine biology & hydrobiology, Ethology, Graph theory, Random walk, Range (mathematics), Identification (information), Remote Sensing Technology, Animal Science and Zoology, Animal Distribution, Dijkstra's algorithm, Reindeer

Abstract

The loss, fragmentation and degradation of habitat everywhere on Earth prompts increasing attention to identifying landscape features that support animal movement (corridors) or impedes it (barriers). Most algorithms used to predict corridors assume that animals move through preferred habitat either optimally (e.g. least cost path) or as random walkers (e.g. current models), but neither extreme is realistic. We propose that corridors and barriers are two sides of the same coin and that animals experience landscapes as spatiotemporally dynamic corridor-barrier continua connecting (separating) functional areas where individuals fulfil specific ecological processes. Based on this conceptual framework, we propose a novel methodological approach that uses high-resolution individual-based movement data to predict corridor-barrier continua with increased realism. Our approach consists of two innovations. First, we use step selection functions (SSF) to predict friction maps quantifying corridor-barrier continua for tactical steps between consecutive locations. Secondly, we introduce to movement ecology the randomized shortest path algorithm (RSP) which operates on friction maps to predict the corridor-barrier continuum for strategic movements between functional areas. By modulating the parameter Ѳ, which controls the trade-off between exploration and optimal exploitation of the environment, RSP bridges the gap between algorithms assuming optimal movements (when Ѳ approaches infinity, RSP is equivalent to LCP) or random walk (when Ѳ → 0, RSP → current models). Using this approach, we identify migration corridors for GPS-monitored wild reindeer (Rangifer t. tarandus) in Norway. We demonstrate that reindeer movement is best predicted by an intermediate value of Ѳ, indicative of a movement trade-off between optimization and exploration. Model calibration allows identification of a corridor-barrier continuum that closely fits empirical data and demonstrates that RSP outperforms models that assume either optimality or random walk. The proposed approach models the multiscale cognitive maps by which animals likely navigate real landscapes and generalizes the most common algorithms for identifying corridors. Because suboptimal, but non-random, movement strategies are likely widespread, our approach has the potential to predict more realistic corridor-barrier continua for a wide range of species.

Published

2015

6. Random walks based modularity

Author

Marco Saerens, Ilkka Kivimäki, Amin Mantrach, Alejandro Jaimes, Robin Devooght, and Hugues Bersini

Subjects

Modularity (networks), Social network, business.industry, Computer science, Semi-supervised learning, Resolution (logic), Random walk, Modularity, Measure (mathematics), Graph, Simple (abstract algebra), Graph (abstract data type), Artificial intelligence, Limit (mathematics), business

Abstract

Although criticized for some of its limitations, modularity remains a standard measure for analyzing social networks. Quantifying the statistical surprise in the arrangement of the edges of the network has led to simple and powerful algorithms. However, relying solely on the distribution of edges instead of more complex structures such as paths limits the extent of modularity. Indeed, recent studies have shown restrictions of optimizing modularity, for instance its resolution limit. We introduce here a novel, formal and well-defined modularity measure based on random walks. We show how this modularity can be computed from paths induced by the graph instead of the traditionally used edges. We argue that by computing modularity on paths instead of edges, more informative features can be extracted from the network. We verify this hypothesis on a semi-supervised classification procedure of the nodes in the network, where we show that, under the same settings, the features of the random walk modularity help to classify better than the features of the usual modularity. Additionally, the proposed approach outperforms the classical label propagation procedure on two data sets of labeled social networks.

Published

2014