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A large-area, spatially continuous assessment of land cover map error and its impact on downstream analyses

A large-area, spatially continuous assessment of land cover map error and its impact on downstream analyses
A large-area, spatially continuous assessment of land cover map error and its impact on downstream analyses
Land cover maps increasingly underlie research into socioeconomic and environmental patterns and processes, including global change. It is known that map errors impact our understanding of these phenomena, but quantifying these impacts is difficult because many areas lack adequate reference data. We used a highly accurate, high-resolution map of South African cropland to assess (1) the magnitude of error in several current generation land cover maps, and (2) how these errors propagate in downstream studies. We first quantified pixel-wise errors in the cropland classes of four widely used land cover maps at resolutions ranging from 1 to 100 km, and then calculated errors in several representative “downstream” (map-based) analyses, including assessments of vegetative carbon stocks, evapotranspiration, crop production, and household food security. We also evaluated maps’ spatial accuracy based on how precisely they could be used to locate specific landscape features. We found that cropland maps can have substantial biases and poor accuracy at all resolutions (e.g., at 1 km resolution, up to ∼45% underestimates of cropland (bias) and nearly 50% mean absolute error (MAE, describing accuracy); at 100 km, up to 15% underestimates and nearly 20% MAE). National-scale maps derived from higher-resolution imagery were most accurate, followed by multi-map fusion products. Constraining mapped values to match survey statistics may be effective at minimizing bias (provided the statistics are accurate). Errors in downstream analyses could be substantially amplified or muted, depending on the values ascribed to cropland-adjacent covers (e.g., with forest as adjacent cover, carbon map error was 200%–500% greater than in input cropland maps, but ∼40% less for sparse cover types). The average locational error was 6 km (600%). These findings provide deeper insight into the causes and potential consequences of land cover map error, and suggest several recommendations for land cover map users.
1354-1013
Estes, Lyndon
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Chen, Peng
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Debats, Stephanie
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Evans, Tom
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Ferreira, Stefanus
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Kuemmerle, Tobias
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Ragazzo, Gabrielle
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Sheffield, Justin
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Wofl, Adam
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Wood, Eric
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Caylor, Kelly
9495817c-5392-47ed-a013-1d02f501aa28
Estes, Lyndon
c36eb710-c314-4074-8845-b16e53c10558
Chen, Peng
8674736c-f500-4163-9196-fd81feaaf569
Debats, Stephanie
f03d50c4-d60b-4a16-929f-2bcdee9e11fc
Evans, Tom
66838d67-c7bc-4c6e-be3d-149970c0f0a3
Ferreira, Stefanus
4ce4621b-c08a-4221-be08-4c7a67ff4742
Kuemmerle, Tobias
e28a33e3-4e2e-49a1-a713-da30e4f23edc
Ragazzo, Gabrielle
f9a1d3aa-152a-4ebe-8cec-5d190c2be64b
Sheffield, Justin
dd66575b-a4dc-4190-ad95-df2d6aaaaa6b
Wofl, Adam
e2b1cec5-7054-4dfc-86da-a47c79bdeb82
Wood, Eric
8352c1b4-4fd3-42fe-bd23-46619024f1cf
Caylor, Kelly
9495817c-5392-47ed-a013-1d02f501aa28

Estes, Lyndon, Chen, Peng, Debats, Stephanie, Evans, Tom, Ferreira, Stefanus, Kuemmerle, Tobias, Ragazzo, Gabrielle, Sheffield, Justin, Wofl, Adam, Wood, Eric and Caylor, Kelly (2017) A large-area, spatially continuous assessment of land cover map error and its impact on downstream analyses. Global Change Biology. (doi:10.1111/gcb.13904).

Record type: Article

Abstract

Land cover maps increasingly underlie research into socioeconomic and environmental patterns and processes, including global change. It is known that map errors impact our understanding of these phenomena, but quantifying these impacts is difficult because many areas lack adequate reference data. We used a highly accurate, high-resolution map of South African cropland to assess (1) the magnitude of error in several current generation land cover maps, and (2) how these errors propagate in downstream studies. We first quantified pixel-wise errors in the cropland classes of four widely used land cover maps at resolutions ranging from 1 to 100 km, and then calculated errors in several representative “downstream” (map-based) analyses, including assessments of vegetative carbon stocks, evapotranspiration, crop production, and household food security. We also evaluated maps’ spatial accuracy based on how precisely they could be used to locate specific landscape features. We found that cropland maps can have substantial biases and poor accuracy at all resolutions (e.g., at 1 km resolution, up to ∼45% underestimates of cropland (bias) and nearly 50% mean absolute error (MAE, describing accuracy); at 100 km, up to 15% underestimates and nearly 20% MAE). National-scale maps derived from higher-resolution imagery were most accurate, followed by multi-map fusion products. Constraining mapped values to match survey statistics may be effective at minimizing bias (provided the statistics are accurate). Errors in downstream analyses could be substantially amplified or muted, depending on the values ascribed to cropland-adjacent covers (e.g., with forest as adjacent cover, carbon map error was 200%–500% greater than in input cropland maps, but ∼40% less for sparse cover types). The average locational error was 6 km (600%). These findings provide deeper insight into the causes and potential consequences of land cover map error, and suggest several recommendations for land cover map users.

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Accepted/In Press date: 24 July 2017
e-pub ahead of print date: 16 September 2017

Identifiers

Local EPrints ID: 425356
URI: http://eprints.soton.ac.uk/id/eprint/425356
DOI: doi:10.1111/gcb.13904
ISSN: 1354-1013
PURE UUID: f7a09d3d-6e66-45aa-92ff-2087c2279903
ORCID for Justin Sheffield: ORCID iD orcid.org/0000-0003-2400-0630

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Date deposited: 15 Oct 2018 16:31
Last modified: 16 Mar 2024 05:54

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Contributors

Author: Lyndon Estes
Author: Peng Chen
Author: Stephanie Debats
Author: Tom Evans
Author: Stefanus Ferreira
Author: Tobias Kuemmerle
Author: Gabrielle Ragazzo
Author: Justin Sheffield ORCID iD
Author: Adam Wofl
Author: Eric Wood
Author: Kelly Caylor

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