Robust Network Design For Multispecies Conservation

Our work is motivated by an important network design application in computational sustainability concerning wildlife conservation. In the face of human development and climate change, it is important that conservation plans for protecting landscape connectivity exhibit certain level of robustness. While previous work has focused on conservation strategies that result in a connected network of habitat reserves, the robustness of the proposed solutions has not been taken into account. In order to address this important aspect, we formalize the problem as a node-weighted bi-criteria network design problem with connectivity requirements on the number of disjoint paths between pairs of nodes. While in most previous work on survivable network design the objective is to minimize the cost of the selected network, our goal is to optimize the quality of the selected paths within a specified budget, while meeting the connectivity requirements. We characterize the complexity of the problem under different restrictions. We provide a mixed-integer programming encoding that allows for finding solutions with optimality guarantees, as well as a hybrid local search method with better scaling behavior but no guarantees. We evaluate the typical-case performance of our approaches using a synthetic benchmark, and apply them to a large-scale real-world network design problem concerning the conservation of wolverine and lynx populations in the U.S. Rocky Mountains (Montana).

[1]  MICHAEL K. SCHWARTZ,et al.  Sources and Patterns of Wolverine Mortality in Western Montana , 2007 .

[2]  Andrew V. Goldberg,et al.  Improved approximation algorithms for network design problems , 1994, SODA '94.

[3]  A. Prasad,et al.  PREDICTING ABUNDANCE OF 80 TREE SPECIES FOLLOWING CLIMATE CHANGE IN THE EASTERN UNITED STATES , 1998 .

[4]  Reed F. Noss,et al.  A Regional Landscape Approach to Maintain Diversity , 1983 .

[5]  Bistra N. Dilkina,et al.  Solving Connected Subgraph Problems in Wildlife Conservation , 2010, CPAIOR.

[6]  Sean A. Parks,et al.  Combining resource selection and movement behavior to predict corridors for Canada lynx at their southern range periphery , 2013 .

[7]  Ashish Sabharwal,et al.  Connections in Networks: A Hybrid Approach , 2008, CPAIOR.

[8]  Paul Beier,et al.  Circuit theory predicts gene flow in plant and animal populations , 2007, Proceedings of the National Academy of Sciences.

[9]  Ali Ridha Mahjoub,et al.  Design of Survivable Networks: A survey , 2005, Networks.

[10]  David Pisinger,et al.  Large Neighborhood Search , 2018, Handbook of Metaheuristics.

[11]  C. Gomes Computational Sustainability: Computational methods for a sustainable environment, economy, and society , 2009 .

[12]  Paul Shaw,et al.  Using Constraint Programming and Local Search Methods to Solve Vehicle Routing Problems , 1998, CP.

[13]  Jon M. Conrad,et al.  Wildlife corridors as a connected subgraph problem , 2012 .

[14]  Kenneth N. Brown,et al.  Exploring the use of constraint programming for enforcing connectivity during graph generation , 2005 .

[15]  Gerardo Rubino,et al.  Network design with node connectivity constraints , 2003, LANC '03.

[16]  David S. Johnson,et al.  Computers and Intractability: A Guide to the Theory of NP-Completeness , 1978 .

[17]  Larry D. Harris,et al.  Nodes, networks, and MUMs: Preserving diversity at all scales , 1986 .

[18]  H. Andrén,et al.  Effects of habitat fragmentation on birds and mammals in landscapes with different proportions of suitable habitat: a review , 1994 .

[19]  Carla P. Gomes,et al.  The Steiner Multigraph Problem: Wildlife Corridor Design for Multiple Species , 2011, AAAI.

[20]  Ehl Emile Aarts,et al.  Local search for Steiner tree problems in graphs , 1996 .

[21]  P. Beier,et al.  Uncertainty analysis of least-cost modeling for designing wildlife linkages. , 2009, Ecological applications : a publication of the Ecological Society of America.

[22]  Otso Ovaskainen,et al.  The metapopulation capacity of a fragmented landscape , 2000, Nature.

[23]  Sean A. Parks,et al.  Climate change predicted to shift wolverine distributions, connectivity, and dispersal corridors , 2011 .

[24]  Philip N. Klein,et al.  An O(n log n) approximation scheme for Steiner tree in planar graphs , 2009, TALG.

[25]  Patrick Prosser,et al.  A Connectivity Constraint Using Bridges , 2006, ECAI.

[26]  David P. Williamson,et al.  A primal-dual approximation algorithm for generalized steiner network problems , 1993, Comb..

[27]  F. Glover,et al.  Handbook of Metaheuristics , 2019, International Series in Operations Research & Management Science.

[28]  John F. Lehmkuhl,et al.  Landscape permeability for large carnivores in Washington: a geographic information system weighted-distance and least-cost corridor assessment. , 2002 .

[29]  Ashish Sabharwal,et al.  Connections in Networks: Hardness of Feasibility Versus Optimality , 2007, CPAIOR.

[30]  Steven J. Phillips,et al.  Optimizing dispersal corridors for the Cape Proteaceae using network flow. , 2008, Ecological applications : a publication of the Ecological Society of America.

[31]  Ronan Le Bras,et al.  Large Landscape Conservation - Synthetic and Real-World Datasets , 2013, AAAI.