Reproducibility and Replicability in Geographical Analysis

Kedron, Peter; Frazier, Amy E.; Trgovac, Andrew B.; Nelson, Trisalyn A.; Fotheringham, A. Stewart

doi:10.1111/gean.12221

Cited by 66 publications

(63 citation statements)

References 62 publications

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“…If we are to consider the stages in the development of software tools following those listed in Table 1, perhaps an interesting further development is that stage 1 has been revisited, particularly in terms of ideas of reproducibility. This captures general view that data analysis carried out in research should, wherever reasonable, be capable of reproduction by a third party (Singleton et al 2016;Wang 2016;Shannon and Walker 2018;Nüst et al 2018;Singleton and Arribas-Bel 2019;Kedron et al 2019). In essence, this requires that any reporting of data analysis should provide the computational procedure used and the data, in addition to a presentation of the outcome of the analysis.…”

Section: Spatial Analysismentioning

confidence: 99%

“…These have emerged for a number of reasons: software costs, distrust of the 'black box' where data are processed without disclosure of the processing method, recognition of the scientific advantages of working in an open source environment where new methods are typically available several years before their availability in commercial software, as well as the wider practice of user community-generated software extensions and improvements-social (geo-) computation, and reproducibility. The distrust of the black box reflects a widely held view that data analysis and research should, wherever reasonable, be capable of reproduction/replication by a third party, where reproducibility is defined is the exact duplication of the results using the same materials, and replicability means confirming original conclusions (Nüst et al 2018), for example, with new data (Kedron et al 2019), both as a scientific credo and to avoid further 'climategates' (Campbell 2010), in which a key issue was that the researchers involved would not release their data (or their code). The need for such transparency derives from the dangers of uncritical acceptance of black box spatial analyses, and the potential for erroneous results of such approaches precisely because 'there is less of a requirement to think about the underlying processes that are being implemented' (Singleton et al 2016(Singleton et al , p. 1512 In essence, a reproducible research philosophy is one which allows all aspects of the answer generated by any given analysis to be tested.…”

Section: Introductionmentioning

confidence: 99%

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Opening practice: supporting reproducibility and critical spatial data science

Brunsdon

Comber

2020

J Geogr Syst

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This paper reflects on a number of trends towards a more open and reproducible approach to geographic and spatial data science over recent years. In particular, it considers trends towards Big Data, and the impacts this is having on spatial data analysis and modelling. It identifies a turn in academia towards coding as a core analytic tool, and away from proprietary software tools offering 'black boxes' where the internal workings of the analysis are not revealed. It is argued that this closed form software is problematic and considers a number of ways in which issues identified in spatial data analysis (such as the MAUP) could be overlooked when working with closed tools, leading to problems of interpretation and possibly inappropriate actions and policies based on these. In addition, this paper considers the role that reproducible and open spatial science may play in such an approach, taking into account the issues raised. It highlights the dangers of failing to account for the geographical properties of data, now that all data are spatial (they are collected somewhere), the problems of a desire for n = all observations in data science and it identifies the need for a critical approach. This is one in which openness, transparency, sharing and reproducibility provide a mantra for defensible and robust spatial data science.

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Section: Spatial Analysismentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Opening practice: supporting reproducibility and critical spatial data science

Brunsdon

Comber

2020

J Geogr Syst

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“…Whether this transfers to geography remains to be seen. Brunsdon (2016) outlines the challenges posed for reproducibility in geography, and Kedron et al (2020) provides a further elaboration the theoretical challenges to replication in geography. Further, Retraction Watch shows retractions in a few geography journals, but these are rare and will hopefully remain so.…”

Section: Reproducibilitymentioning

confidence: 99%

Quantitative Geography III: Future Challenges & Challenging Futures

Wolf¹,

Fox²,

Harris³

et al. 2020

Preprint

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In the previous two parts of this series, we discussed the history and current status of quantitative geography. In this final part, we focus on the future. We argue that quantitative geographers are most helpful when we can simplify difficult problems using our distinct domain expertise. To do this, we must clarify the theory underpinning core conceptual problems in quantitative geography. Then, we examine the social forces that are shaping the future of quantitative geography. We conclude with criteria for how quantitative geography might succeed in addressing these challenges.

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“…Urban planning and its related disciplines benefit accordingly from the growing adoption of computational notebooks in pedagogy, research, and practice. Computation is increasingly central to the field and its practitioners benefit from open and reproducible approaches to analyzing urban data and predicting city futures (Kedron et al 2019;Kontokosta 2018;Batty 2019). In the Python universe, for example, numerous new tools now exist to support urban analytics and planning processes, including data wrangling/analysis (pandas), visualization (matplotlib), geospatial wrangling/analysis (geopandas), spatial data science and econometrics (pySAL), mapping (cartopy), web mapping (folium), network analysis (NetworkX), land use modeling/simulation (Ur-banSim), activity-based travel modeling (ActivitySim), and computational notebooks themselves (Jupyter).…”

Section: Introductionmentioning

confidence: 99%

Urban Street Network Analysis in a Computational Notebook

Boeing

2020

REGION

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Computational notebooks offer researchers, practitioners, students, and educators the ability to interactively conduct analytics and disseminate reproducible workflows that weave together code, visuals, and narratives. This article explores the potential of computational notebooks in urban analytics and planning, demonstrating their utility through a case study of OSMnx and its tutorials repository. OSMnx is a Python package for working with OpenStreetMap data and modeling, analyzing, and visualizing street networks anywhere in the world. Its official demos and tutorials are distributed as open-source Jupyter notebooks on GitHub. This article showcases this resource by documenting the repository and demonstrating OSMnx interactively through a synoptic tutorial adapted from the repository. It illustrates how to download urban data and model street networks for various study sites, compute network indicators, visualize street centrality, calculate routes, and work with other spatial data such as building footprints and points of interest. Computational notebooks help introduce methods to new users and help researchers reach broader audiences interested in learning from, adapting, and remixing their work. Due to their utility and versatility, the ongoing adoption of computational notebooks in urban planning, analytics, and related geocomputation disciplines should continue into the future. 1

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Reproducibility and Replicability in Geographical Analysis

Cited by 66 publications

References 62 publications

Opening practice: supporting reproducibility and critical spatial data science

Opening practice: supporting reproducibility and critical spatial data science

Quantitative Geography III: Future Challenges & Challenging Futures

Urban Street Network Analysis in a Computational Notebook

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Reproducibility and Replicability in Geographical Analysis

Cited by 66 publications

References 62 publications

Opening practice: supporting reproducibility and critical spatial data science

Opening practice: supporting reproducibility and critical spatial data science

Quantitative Geography III: Future Challenges &amp; Challenging Futures

Urban Street Network Analysis in a Computational Notebook

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Quantitative Geography III: Future Challenges & Challenging Futures