Buffer analysis explained

In geographic information systems (GIS) and spatial analysis, buffer analysis is the determination of a zone around a geographic feature containing locations that are within a specified distance of that feature, the buffer zone (or just buffer).[1] A buffer is likely the most commonly used tool within the proximity analysis methods.[2]

History

The buffer operation has been a core part of GIS functionality since the original integrated GIS software packages of the late 1970s and early 1980s, such as ARC/INFO, Odyssey, and MOSS. Although it has been one of the most widely used GIS operations in subsequent years, in a wide variety of applications, there has been little published research on the tool itself, except for the occasional development of a more efficient algorithm.[3]

Basic algorithm

The fundamental method to create a buffer around a geographic feature stored in a vector data model, with a given radius r is as follows:[4]

  1. Create a circle buffer around each vertex
  2. Create a rectangle along each line segment by creating a duplicate line segment offset the distance r perpendicular to each side.
  3. Merge or dissolve the rectangles and circles into a single polygon.

Software implementations of the buffer operation typically use alterations of this strategy to process more efficiently and accurately.

In Mathematics, GIS Buffer operation is a Minkowski Sum (or difference) of a geometry and a disk. Other terms used: Offsetting a Polygon.[5]

Planar vs. geodesic distance

Traditional implementations assumed the buffer was being created on a planar cartesian coordinate space (i.e., created by a map projection) using Euclidean geometry, because the mathematics and computation involved is relatively simple, which was important given the computing power available in the late 1970s. Due to the inherent distortions caused by map projections, the buffer computed this way will not be identical to one drawn on the surface of the Earth; at a local scale, the difference is negligible, but at larger scales, the error can be significant.

Some current software, such as Esri ArcGIS Pro, offer the option to compute buffers using geodesic distance, using a similar algorithm but calculated using spherical trigonometry, including representing the lines between vertices as great circles. Other implementations use a workaround by first reprojecting the feature to a projection that minimizes distortion in that location, then computing the planar buffer.[6]

Options

GIS software may offer variations on the basic algorithm, which may be useful in different applications:

See also

External links

Notes and References

  1. Book: de Smith . Michael J. . Goodchild . Michael F. . Longley . Paul A. . Geospatial Analysis: A Comprehensive Guide to Principles, Techniques, and Software Tools . 2018 . 6th . 4.4.5 Buffering. https://www.spatialanalysisonline.com/HTML/index.html?buffering.htm.
  2. Wade, T. and Smmer, S. eds. A to Z GIS
  3. Bhatia . Sumeet . Vira . Viral . Choksi . Deepak . Venkatachalam . P. . An algorithm for generating geometric buffers for vector feature layers . Geo-spatial Information Science . 2012 . 16 . 2 . 130–138 . 10.1080/10095020.2012.747643. free .
  4. Web site: How Buffer (Analysis) Works . ArcGIS Pro Documentation . Esri . 16 March 2021.
  5. Web site: CGAL 5.6 - 2D Minkowski Sums: User Manual . 2023-11-21 . doc.cgal.org.
  6. Web site: ST_Buffer . PostGIS documentation . 2012-11-02 . 2021-05-07 . https://web.archive.org/web/20210507025544/http://www.postgis.org/docs/ST_Buffer.html . dead .