Geo Spatial Data

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The proliferation of remote sensing technology has created new opportunities for high-resolution, affordable geospatial data, which have great potential as a source of impact evaluation data.








Guidelines

Repositories of Spatial Data

The following are repositories of spatial data. The following sites pull in spatial data from a variety of sources.

Satellite-Based Datasets

The following are commonly used datasets from satellite imagery or derived from satellite imagery.

Dataset Spatial Resolution Temporal Resolution Description
Nighttime Lights: VIIRS 300m Monthly, 2012 to Present Nighttime lights has increasingly been used as a metric for local economic development.
Nighttime Lights: DMSP-OLS 750m Annual, 1992-2013 For studies that need a long time series of nighttime lights, DMSP-OLS data can be combined with VIIRS data. VIIRS, however, has several improvements over DMSP-OLS, including a high resolution and less light saturation in urban areas.
Landsat 30m Every 16 days, 1972 to Present Landsat images capture the earth across multiple spectral bands, including spectra unobservable to the human eye. Different combinations of these spectral bands emphasize different aspects of the earth. One of the most common indices is the Normalized Difference Vegetation Index (NDVI), which provides a measure of vegetation biomass. A list of common indices can be found here.
ESA Land Cover 300m Annual, 1992 to 2015 Classifies land cover into one of 22 land cover types.

Georeferenced Data Sources

Impact Evaluation with Geospatial Data

The emergence of georeferenced data has provided opportunities to evaluate foreign investments at lower costs than traditional RCTs. These evaluations have been dubbed Geospatial Impact Evaluations (GIEs); see here for a working paper from AidData that describes methods and applications to perform GIEs. The paper describes a number of papers that conduct GIEs. In addition, it highlights two R packages that employ methods relevant to using geospatial data: (1) geoMATCH, which employs matching while accounting for geographic spillover from treatment to control units and (2) geoSIMEX, which allows users to account for spatial imprecision in analysis.

Use of intersection to produce usable data for Stata

  • For a particular project that has a spatial component, you first need to have geographical polygons that are representative of your project. For instance, the polygons that shows the limits of your villages.
  • Then, for some particular themes you will only find data in the form of GIS data. Examples of this are hospitals and clinics, or rainfall. The data in question is then intrinsically accompanied with coordinates, that allows to position the information in a spatial setting.
  • So then, after importing the particular data to a GIS software, you overlay your new data to the geographical layer that represents your project.
  • Once done, and simply intersect both layers, and ask for instance for a mean over your geographical polygons, or for a maximum or for a count. In QGIS, for instance, you will find a bunch of these useful spacial operations in the Vector/Geoprocessing Tools section.
  • These tools also allow you for instance to substract polygons from others; Then why not intersecting with data layer afterwards? It is much useful.
  • All that needs to be done then is to export your newly generated data.

Data Interpolation

This is useful for those who want to generate information in between spatial measurements. You will not want to this is several settings, since the granularity of your data has a value. However for some themes, like for the level of a groundwater table, or for the level of a ground contamination, this is useful as the nature of the subject itself (ex: contamination) is continuous.

  • The main thing one should know, is that the mathematical method you chose for the interpolation has a large impact on your results.
  • In case of doubts (or in much of cases, let's say), one should chose to use krigging, since the interpolation (let's visualize it as a surface) goes through the measurement points exactly. It's distance at a measurement point is equal to zero.
  • GIS softwares usually have modules that allow to do interpolation. They also allow to do dynamic modelling (state of your variables, in space, with time).
  • The interpolation of your data lead to the production of heat maps.

Heat Maps

  • When producing heat maps, one should know that there exist mathematical tools that allow you to enhance the spatial shapes that your data.
  • These "tools" are in fact transformations on your surface, such as first difference, Fourrier, ect. They can provide a much better definition of your results, and even allow you to "see" something that you might have missed when not using them.

Examples of Papers

  • Many influential papers using these type of data have been published in journals

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This article is part of the topic Secondary Data Sources

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