Geoweaver: Advanced Cyberinfrastructure for Managing Hybrid Geoscientific AI Workflows

Sun, Ziheng; Di, Liping; Burgess, Annie; Tullis, Jason A.; Magill, Andrew

doi:10.3390/ijgi9020119

Cited by 25 publications

(10 citation statements)

References 88 publications

(94 reference statements)

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“…An advanced workflow management system is used to automate the tedious large dataset processing, to enhance time efficiency and reduce scientific reproducibility issues [13], [16], [24]. We implemented the DNN crop mapping workflow in Geoweaver-an open-source web-based workflow system [25]- [27], to help us integrate distributed resources, automate the pre/postprocessing workflows and track the provenance of the final crop maps [25]. Training DNN models is a back-and-forth process and requires a lot of skills and expertise.…”

Section: Introductionmentioning

confidence: 99%

Deep Learning Classification for Crop Types in North Dakota

Sun

Fang

et al. 2020

IEEE J. Sel. Top. Appl. Earth Observations Remote Sensing

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Recently, agricultural remote sensing community has endeavored to utilize the power of artificial intelligence (AI). One important topic is using AI to make the mapping of crops more accurate, automatic, and rapid. This article proposed a classification workflow using deep neural network (DNN) to produce high-quality in-season crop maps from Landsat imageries for North Dakota. We use historical crop maps from the agricultural department and North Dakota ground measurements as training datasets. Processing workflows are created to automate the tedious preprocessing, training, testing, and postprocessing workflows. We tested this hybrid solution on new images and received accurate results on major crops such as corn, soybean, barley, spring wheat, dry beans, sugar beets, and alfalfa. The pixelwise overall accuracy in all three test regions is over 82% for all land types (including noncrop land), which is the same level of accuracy as the U.S. Department of Agriculture Cropland Data Layer. The texture of DNN maps is more consistent with fewer noises, which is more comfortable to read. We find DNN is better on recognizing big farmlands than recognizing the scattered wetlands and suburban regions in North Dakota. The model trained on multiple scenes of multiple years and months yields higher accuracy than any of the models trained only on a single scene, a single month, or a single year. These results reflect that DNN can produce reliable in-season maps for major crops in North Dakota big farms and could provide a relatively accurate reference for the minor crops in scattered wetland fields.

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Section: Introductionmentioning

confidence: 99%

Deep Learning Classification for Crop Types in North Dakota

Sun

Fang

et al. 2020

IEEE J. Sel. Top. Appl. Earth Observations Remote Sensing

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“…First, GIScience should encourage more practical demonstrations of multiuser provenance interchange that accelerate R&R (N€ ust and Pebesma 2020; Wilson et al 2020), regardless of whether the software environments are open source or commercial, workstation or cloud based, or code versus graphic block programming (Tullis et al 2015;Tullis et al 2019). Much work remains in how to compress, store, and otherwise manage provenance records throughout their life cycle (Sun et al 2020), issues that are continually emerging in discussions on GIScience workflows (OGC 2020). Even though the W3C created the powerful PROV data model (PROV-DM; Moreau and Missier 2013) almost a decade ago, GIScience applications of PROV have been very rare (Tullis et al 2019).…”

Section: Current Practice and Recommendations For Innovation Provenancementioning

confidence: 99%

“…Even though the W3C created the powerful PROV data model (PROV-DM; Moreau and Missier 2013) almost a decade ago, GIScience applications of PROV have been very rare (Tullis et al 2019). Successful, practical demonstrations of artificial intelligence and hybrid GIScience workflow management (e.g., Sun et al 2020) challenge software engineering teams to accelerate support for provenance interchange and workflow standards and specifications from authoritative sources such as W3C and OGC.…”

Section: Current Practice and Recommendations For Innovation Provenancementioning

confidence: 99%

Where Is the Provenance? Ethical Replicability and Reproducibility in GIScience and Its Critical Applications

Tullis¹,

Kar

2020

Annals of the American Association of Geographers

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As replicability and reproducibility (R&R) crises develop within emerging convergent inquiry, ethical use of provenance information is central to the establishment and preservation of trust in critical applications of GIScience and geospatial technologies. Today large volumes of geospatial data are generated at high velocity from satellite sensors and unmanned aircraft systems, citizen sensors, geolocation-based data services, global navigation satellite systems, and so on. The extensive use of these data for applications such as disaster and humanitarian response raises the issue of R&R from competing perspectives of location privacy and geospatial data quality. Although geospatial data can be integrated and linked with contextual information to identify individuals' movements, steps taken to ensure privacy can complicate the multiuser development of high-quality geospatial workflows. Provenance information as digital records of historical (retrospective) and potential future (prospective) geospatial processes is often overlooked, misunderstood, or inadequately addressed. We explore the relationship between provenance information, location privacy, and geospatial data quality in the context of R&R with a focus on disaster analytics. We argue that in the era of big data and deep learning, GIScientists and associated institutions bear greater responsibility both for geospatial workflow quality and for location privacy. Given vastly heterogenous computational landscapes, we provide practical recommendations for ethically driven provenance and R&R research and development within the GIScience community and beyond.

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“…A large portion of the costs in reusing existing services is charged by this step. The common processes to unify the datasets include reprojection, resampling, regridding, reformatting, mosaic, merging, getting location reports, etc [48,49]. Most web services do all the preprocessing work.…”

Section: Data Extraction and Fusion Submodulementioning

confidence: 99%

GeoFairy2: A Cross-Institution Mobile Gateway to Location-Linked Data for In-Situ Decision Making

Sun

Cvetojevic

et al. 2020

IJGI

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To effectively disseminate location-linked information despite the existence of digital walls across institutions, this study developed a cross-institution mobile App, named GeoFairy2, to overcome the virtual gaps among multi-source datasets and aid the general users to make thorough accurate in-situ decisions. The app provides a one-stop service with relevant information to assist with instant decision making. It was tested and proven to be capable of on-demand coupling and delivering location-based information from multiple sources. The app can help general users to crack down the digital walls among information pools and serve as a one-stop retrieval place for all information. GeoFairy2 was experimented with to gather real-time and historical information about crops, soil, water, and climate. Instead of a one-way data portal, GeoFairy2 allows general users to submit photos and observations to support citizen science projects and derive new insights, and further refine the future service. The two-directional mechanism makes GeoFairy2 a useful mobile gateway to access and contribute to the rapidly growing, heterogeneous, multisource, and location-linked datasets, and pave a way to drive us into a new mobile web with more links and less digital walls across data providers and institutions.

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Geoweaver: Advanced Cyberinfrastructure for Managing Hybrid Geoscientific AI Workflows

Cited by 25 publications

References 88 publications

Deep Learning Classification for Crop Types in North Dakota

Deep Learning Classification for Crop Types in North Dakota

Where Is the Provenance? Ethical Replicability and Reproducibility in GIScience and Its Critical Applications

GeoFairy2: A Cross-Institution Mobile Gateway to Location-Linked Data for In-Situ Decision Making

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