Building a multi-scaled geospatial temporal ecology database from disparate data sources: fostering open science and data reuse

Soranno, Patricia A.; Bissell, Edward G.; Cheruvelil, Kendra Spence; Christel, Samuel T.; Collins, Sarah M.; Fergus, C. Emi; Filstrup, Christopher T.; Lapierre, Jean‐François; Lottig, Noah R.; Oliver, Samantha; Scott, Catherine; Smith, Nicole J.; Stopyak, Scott B.; Yuan, Shuai; Bremigan, Mary T.; Downing, John A.; Gries, Corinna; Henry, Emily Norton; Skaff, Nick K.; Stanley, Emily H.; Stow, Craig A.; Tan, Pang‐Ning; Wagner, Tyler; Webster, Katherine E.

doi:10.1186/s13742-015-0067-4

Cited by 98 publications

(161 citation statements)

References 35 publications

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“…A large-scale study may call for the integration of many different types of data, creating philosophical, logistical, and analytical challenges (Jones et al 2006, Soranno et al 2015). …”

Section: Key Skills For the Data-intensive Environmental Scientistmentioning

confidence: 99%

Skills and Knowledge for Data-Intensive Environmental Research

Hampton¹,

Jones²,

Wasser³

et al. 2017

BioScience

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The scale and magnitude of complex and pressing environmental issues lend urgency to the need for integrative and reproducible analysis and synthesis, facilitated by data-intensive research approaches. However, the recent pace of technological change has been such that appropriate skills to accomplish data-intensive research are lacking among environmental scientists, who more than ever need greater access to training and mentorship in computational skills. Here, we provide a roadmap for raising data competencies of current and next-generation environmental researchers by describing the concepts and skills needed for effectively engaging with the heterogeneous, distributed, and rapidly growing volumes of available data. We articulate five key skills: (1) data management and processing, (2) analysis, (3) software skills for science, (4) visualization, and (5) communication methods for collaboration and dissemination. We provide an overview of the current suite of training initiatives available to environmental scientists and models for closing the skill-transfer gap.

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“…A large-scale study may call for the integration of many different types of data, creating philosophical, logistical, and analytical challenges (Jones et al 2006, Soranno et al 2015). …”

Section: Key Skills For the Data-intensive Environmental Scientistmentioning

confidence: 99%

Skills and Knowledge for Data-Intensive Environmental Research

Hampton¹,

Jones²,

Wasser³

et al. 2017

BioScience

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“…1) that includes the midwestern and northeastern United States. The data were partially acquired from LAGOS, an existing integrated geospatial database assembled by our research team at Michigan State University (Soranno et al 2015) that includes wetland data from the National Wetlands Inventory (NWI), stream data from the National Hydrography Dataset (NHD), as well as the novel wetland metrics that we derived from these datasets (National Wetland Inventory 2014; National Hydrography Dataset 2007). We independently obtained Palmer hydrological drought indices (PHDI) from National Oceanic and Atmospheric Administration (NOAA) and human WNV incidence data from the Centers for Disease Control and Prevention (CDC) and combined these data with the LAGOS-derived data (ArboNET Database 2013; National Climate Data Center 2014).…”

Section: Study Region and Incorporated Datasetsmentioning

confidence: 99%

“…We also used the LAGOS-GIS Toolbox to calculate wetland hydrological connectivity, which we define as wetland connections to streams (Soranno et al 2015). Stream locational data were acquired from the high-resolution, 1:24,000 scale NHD that includes several different feature sets including NHDArea features and NHDFlowline features (National Hydrography Dataset 2007).…”

Section: Wetland and Climate Metricsmentioning

confidence: 99%

Fine-scale wetland features mediate vector and climate-dependent macroscale patterns in human West Nile virus incidence

Skaff

Cheruvelil

2016

Landscape Ecol

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Context Mosquito-borne diseases in the United States are notorious for their seemingly erratic temporal and spatial outbreak patterns in humans. Identifying linkages between fine-scale phenomenon and macroscale outbreak patterns can improve the understanding of these complex socio-ecological systems. Objectives Using West Nile virus (WNV) as a model system, we examine whether fine-scale wetland characteristics-wetland size, connectivity, and inundation regime-have an important effect on macroscale human disease outbreak in the northeastern and midwestern United States. Methods We take a spatially explicit GIS-based approach, derive new macroscale wetland metrics based on fine-scale wetland characteristics, and use county-level annual human WNV incidence data over 11 years to evaluate linkages between the fine and macroscales (1.6 million km 2 ). Results In regions dominated by the Culex tarsalis WNV vector, U.S. counties with a small average wetland size had more than 100 % higher human WNV incidence than counties with a large average wetland size. In regions dominated by the Cx. pipiens and Cx. restuans vectors, a low proportional area of connected wetland was associated with at least 50 % higher human WNV incidence than a high proportional area of connected wetland. Finally, Cx. tarsalisdominated counties with a high proportional area of semi-permanent wetland that were experiencing drought conditions had over 300 % higher annual WNV incidence than drought-affected counties with a low proportional area of semi-permanent wetland. Conclusions Our results suggest that phenomena occurring at the individual wetland scale may aggregate to influence macroscale human WNV outbreak patterns and may be mediated by the interplay of other factors such as vector species-specific traits and climate.

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“…To illustrate the advantages of using SVR, we have compared its performance to other regression methods on four lake water quality data sets obtained from the LAGOS database [14]. Details about the data sets can be found in Section 5.…”

Section: Support Vector Regression (Svr)mentioning

confidence: 99%

“…We used several lake water quality data sets from LAGOS [14], which is a geo-spatial database that contains landscape characterization features and lake water quality data measured at multiple scales covering 17 states in the United States. We used four lake water quality variables-total phosphorus (TP), total nitrogen (TN), total chlorophyll-a (chla) and Secchi depth (Secchi)-as response variables, creating 4 distinct data sets for our experiments.…”

Section: Lake Water Quality Datamentioning

confidence: 99%

Hash-Based Feature Learning for Incomplete Continuous-Valued Data

Yuan

Tan²,

Cheruvelil

et al. 2017

Proceedings of the 2017 SIAM International Conference on Data Mining

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Hash-based feature learning is a widely-used data mining approach for dimensionality reduction and for building linear models that are comparable in performance to their nonlinear counterpart. Unfortunately, such an approach is inapplicable to many real-world data sets because they are often riddled with missing values. Substantial data preprocessing is therefore needed to impute the missing values before the hash-based features can be derived. Biases can be introduced during this preprocessing because it is performed independently of the subsequent modeling task, which can result in the models constructed from the imputed hash-based features being suboptimal. To overcome this limitation, we present a novel framework called H-FLIP that simultaneously estimates the missing values while constructing a set of nonlinear hash-based features from the incomplete data. The effectiveness of the framework is demonstrated through experiments using both synthetic and real-world data sets.

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Building a multi-scaled geospatial temporal ecology database from disparate data sources: fostering open science and data reuse

Cited by 98 publications

References 35 publications

Skills and Knowledge for Data-Intensive Environmental Research

Skills and Knowledge for Data-Intensive Environmental Research

Fine-scale wetland features mediate vector and climate-dependent macroscale patterns in human West Nile virus incidence

Hash-Based Feature Learning for Incomplete Continuous-Valued Data

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