Socio-ecological network structures from process graphs

We propose a process graph (P-graph) approach to develop ecosystem networks from knowledge of the properties of the component species. Originally developed as a process engineering tool for designing industrial plants, the P-graph framework has key advantages over conventional ecological network ana...

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Main Authors: Lao, Angelyn, Cabezas, Heriberto, Orosz, Akos, Friedler, Ferenc, Tan, Raymond Girard R.
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Online Access:https://animorepository.dlsu.edu.ph/faculty_research/425
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Institution: De La Salle University
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spelling oai:animorepository.dlsu.edu.ph:faculty_research-14242022-01-03T06:43:08Z Socio-ecological network structures from process graphs Lao, Angelyn Cabezas, Heriberto Orosz, Akos Friedler, Ferenc Tan, Raymond Girard R. We propose a process graph (P-graph) approach to develop ecosystem networks from knowledge of the properties of the component species. Originally developed as a process engineering tool for designing industrial plants, the P-graph framework has key advantages over conventional ecological network analysis techniques based on input-output models. A P-graph is a bipartite graph consisting of two types of nodes, which we propose to represent components of an ecosystem. Compartments within ecosystems (e.g., organism species) are represented by one class of nodes, while the roles or functions that they play relative to other compartments are represented by a second class of nodes. This bipartite graph representation enables a powerful, unambiguous representation of relationships among ecosystem compartments, which can come in tangible (e.g., mass flow in predation) or intangible form (e.g., symbiosis). For example, within a P-graph, the distinct roles of bees as pollinators for some plants and as prey for some animals can be explicitly represented, which would not otherwise be possible using conventional ecological network analysis. After a discussion of the mapping of ecosystems into P-graph, we also discuss how this framework can be used to guide understanding of complex networks that exist in nature. Two component algorithms of P-graph, namely maximal structure generation (MSG) and solution structure generation (SSG), are shown to be particularly useful for ecological network analysis. These algorithms enable candidate ecosystem networks to be deduced based on current scientific knowledge on the individual ecosystem components. This method can be used to determine the (a) effects of loss of specific ecosystem compartments due to extinction, (b) potential efficacy of ecosystem reconstruction efforts, and (c) maximum sustainable exploitation of human ecosystem services by humans. We illustrate the use of P-graph for the analysis of ecosystem compartment loss using a small-scale stylized case study, and further propose a new criticality index that can be easily derived from SSG results. © 2020 Lao et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited. 2020-08-01T07:00:00Z text text/html https://animorepository.dlsu.edu.ph/faculty_research/425 Faculty Research Work Animo Repository Bipartite graphs Biotic communities Mathematics Operations Research, Systems Engineering and Industrial Engineering
institution De La Salle University
building De La Salle University Library
continent Asia
country Philippines
Philippines
content_provider De La Salle University Library
collection DLSU Institutional Repository
topic Bipartite graphs
Biotic communities
Mathematics
Operations Research, Systems Engineering and Industrial Engineering
spellingShingle Bipartite graphs
Biotic communities
Mathematics
Operations Research, Systems Engineering and Industrial Engineering
Lao, Angelyn
Cabezas, Heriberto
Orosz, Akos
Friedler, Ferenc
Tan, Raymond Girard R.
Socio-ecological network structures from process graphs
description We propose a process graph (P-graph) approach to develop ecosystem networks from knowledge of the properties of the component species. Originally developed as a process engineering tool for designing industrial plants, the P-graph framework has key advantages over conventional ecological network analysis techniques based on input-output models. A P-graph is a bipartite graph consisting of two types of nodes, which we propose to represent components of an ecosystem. Compartments within ecosystems (e.g., organism species) are represented by one class of nodes, while the roles or functions that they play relative to other compartments are represented by a second class of nodes. This bipartite graph representation enables a powerful, unambiguous representation of relationships among ecosystem compartments, which can come in tangible (e.g., mass flow in predation) or intangible form (e.g., symbiosis). For example, within a P-graph, the distinct roles of bees as pollinators for some plants and as prey for some animals can be explicitly represented, which would not otherwise be possible using conventional ecological network analysis. After a discussion of the mapping of ecosystems into P-graph, we also discuss how this framework can be used to guide understanding of complex networks that exist in nature. Two component algorithms of P-graph, namely maximal structure generation (MSG) and solution structure generation (SSG), are shown to be particularly useful for ecological network analysis. These algorithms enable candidate ecosystem networks to be deduced based on current scientific knowledge on the individual ecosystem components. This method can be used to determine the (a) effects of loss of specific ecosystem compartments due to extinction, (b) potential efficacy of ecosystem reconstruction efforts, and (c) maximum sustainable exploitation of human ecosystem services by humans. We illustrate the use of P-graph for the analysis of ecosystem compartment loss using a small-scale stylized case study, and further propose a new criticality index that can be easily derived from SSG results. © 2020 Lao et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
format text
author Lao, Angelyn
Cabezas, Heriberto
Orosz, Akos
Friedler, Ferenc
Tan, Raymond Girard R.
author_facet Lao, Angelyn
Cabezas, Heriberto
Orosz, Akos
Friedler, Ferenc
Tan, Raymond Girard R.
author_sort Lao, Angelyn
title Socio-ecological network structures from process graphs
title_short Socio-ecological network structures from process graphs
title_full Socio-ecological network structures from process graphs
title_fullStr Socio-ecological network structures from process graphs
title_full_unstemmed Socio-ecological network structures from process graphs
title_sort socio-ecological network structures from process graphs
publisher Animo Repository
publishDate 2020
url https://animorepository.dlsu.edu.ph/faculty_research/425
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