Abstract S ustainability is a dynamic, complex and composite data relationship among geographically distributed human and environment ecosystems. The ecosystems may have strong interactions among their elements and processes, but with dynamic implicit boundaries. Multi-scalable and multidimensional ecosystems have significance based on a commonality of basic structural units and domains. We intend to develop a holistic information system for managing different ecosystems within a sustainability framework/context, using an empirical qualitative and quantitative interpretation and analysis of the measured observations. Design Science Research (DSR) approach is aimed at developing an information system using the volumes of unstructured Big Data observations. Collaborating multiple domains, interpreting and evaluating the commonality, uncovering the connectivity among multiple systems are key aspects of the study. The Design Science Information System (DSIS), evolved from DSR approach is used in solving the ecosystem issues associated with multiple domains, in which the sustainability challenges manifest. In this context, we propose a human-environment-economic ecosystem (HEES) framework consisting of human, environment and economic elements and processes. In broad terms, human, environment and economic domains are conceptualized as different players/agents that operate within a range of sustainability scenarios. This approach recognizes the existing constraints of the systems as well as the emerging knowledge of the boundaries of ecosystems and their connectivity. The connectivity and interaction among the systems are analyzed by data mining, visualization and interpretation artefacts within a sustainability policy framework.
[1]
Shastri L. Nimmagadda.
Data Warehousing for Mining of Heterogeneous Data Sources
,
2015
.
[2]
Robert Meersman,et al.
Scalability and knowledge reusability in ontology modeling
,
2002
.
[3]
Veda C. Storey,et al.
An ontological analysis of the relationship construct in conceptual modeling
,
1999,
TODS.
[4]
Peter Rob,et al.
Database systems : design, implementation, and management
,
2000
.
[5]
P. Martens,et al.
Sustainable development: how to manage something that is subjective and never can be achieved?
,
2007
.
[6]
Gary R. Burke,et al.
Making viability sustainable
,
2012
.
[7]
Jan Pries-Heje,et al.
FEDS: a Framework for Evaluation in Design Science Research
,
2016,
Eur. J. Inf. Syst..
[8]
Shastri L. Nimmagadda,et al.
On big data guided embedded digital ecosystems (EDE) and their knowledge management
,
2016,
2016 IEEE 14th International Conference on Industrial Informatics (INDIN).
[9]
John Handmer,et al.
Ecology, Uncertainty and Policy: Managing Ecosystems for Sustainability
,
2001
.
[10]
Tom A. August,et al.
Declining resilience of ecosystem functions under biodiversity loss
,
2015,
Nature Communications.