Improving the accuracy of land cover classiﬁcation in cloud persistent areas using optical and radar satellite image time series

Jane Katharine Hill; Mailys  Lopes; Pierre-Louis  Frison; Merry Crowson; Eleanor May Warren-Thomas; Bambang Hariyadi; Winda D. Kartika; Fahmuddin Agus; Keith C. Hamer; Lindsay C. Stringer; Nathalie Pettorelli

doi:10.1111/2041-210X.13359

Improving the accuracy of land cover classiﬁcation in cloud persistent areas using optical and radar satellite image time series

Jane Katharine Hill, Mailys Lopes, Pierre-Louis Frison, Merry Crowson, Eleanor May Warren-Thomas, Bambang Hariyadi, Winda D. Kartika, Fahmuddin Agus, Keith C. Hamer, Lindsay C. Stringer, Nathalie Pettorelli

Biology

Research output: Contribution to journal › Article › peer-review

Abstract

The recent availability of high spatial and temporal resolution optical and radar satellite imagery has dramatically increased opportunities for mapping land cover at fine scales. Fusion of optical and radar images has been found useful in tropical areas affected by cloud cover because of their complementarity. However, the multitemporal dimension these data now offer is often neglected because these areas are primarily characterized by relatively low levels of seasonality and because the consideration of multitemporal data requires more processing time. Hence, land cover mapping in these regions is often based on imagery acquired for a single date or on an average of multiple dates.
The aim of this work is to assess the added value brought by the temporal dimension of optical and radar time series when mapping land cover in tropical environments. Specifically, we compared the accuracies of classifications based on (a) optical time series, (b) their temporal average, (c) radar time series, (d) their temporal average, (e) a combination of optical and radar time series and (f) a combination of their temporal averages for mapping land cover in Jambi province, Indonesia, using Sentinel-1 and Sentinel-2 imagery.
Using the full information contained in the time series resulted in significantly higher classification accuracies than using temporal averages (+14.7% for Sentinel-1, +2.5% for Sentinel-2 and +2% combining Sentinel-1 and Sentinel-2). Overall, combining Sentinel-2 and Sentinel-1 time series provided the highest accuracies (Kappa = 88.5%).
Our study demonstrates that preserving the temporal information provided by satellite image time series can significantly improve land cover classifications in tropical biodiversity hotspots, improving our capacity to monitor ecosystems of high conservation relevance such as peatlands. The proposed method is reproducible, automated and based on open-source tools satellite imagery.

Original language	English
Pages (from-to)	532-541
Number of pages	10
Journal	Methods in ecology and evolution
Volume	11
Issue number	4
Early online date	27 Jan 2020
DOIs	https://doi.org/10.1111/2041-210X.13359
Publication status	Published - 2 Apr 2020

Bibliographical note

© 2020 British Ecological Society. This is an author-produced version of the published paper. Uploaded in accordance with the publisher’s self-archiving policy. Further copying may not be permitted; contact the publisher for details.

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© 2020 British Ecological Society. This is an author-produced version of the published paper. Uploaded in accordance with the publisher’s self-archiving policy. Further copying may not be permitted; contact the publisher for details.
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Cite this

Hill, J. K., Lopes, M., Frison, P.-L., Crowson, M., Warren-Thomas, E. M., Hariyadi, B., Kartika, W. D., Agus, F., Hamer, K. C., Stringer, L. C., & Pettorelli, N. (2020). Improving the accuracy of land cover classiﬁcation in cloud persistent areas using optical and radar satellite image time series. Methods in ecology and evolution, 11(4), 532-541. https://doi.org/10.1111/2041-210X.13359

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abstract = "The recent availability of high spatial and temporal resolution optical and radar satellite imagery has dramatically increased opportunities for mapping land cover at fine scales. Fusion of optical and radar images has been found useful in tropical areas affected by cloud cover because of their complementarity. However, the multitemporal dimension these data now offer is often neglected because these areas are primarily characterized by relatively low levels of seasonality and because the consideration of multitemporal data requires more processing time. Hence, land cover mapping in these regions is often based on imagery acquired for a single date or on an average of multiple dates.The aim of this work is to assess the added value brought by the temporal dimension of optical and radar time series when mapping land cover in tropical environments. Specifically, we compared the accuracies of classifications based on (a) optical time series, (b) their temporal average, (c) radar time series, (d) their temporal average, (e) a combination of optical and radar time series and (f) a combination of their temporal averages for mapping land cover in Jambi province, Indonesia, using Sentinel-1 and Sentinel-2 imagery.Using the full information contained in the time series resulted in significantly higher classification accuracies than using temporal averages (+14.7% for Sentinel-1, +2.5% for Sentinel-2 and +2% combining Sentinel-1 and Sentinel-2). Overall, combining Sentinel-2 and Sentinel-1 time series provided the highest accuracies (Kappa = 88.5%).Our study demonstrates that preserving the temporal information provided by satellite image time series can significantly improve land cover classifications in tropical biodiversity hotspots, improving our capacity to monitor ecosystems of high conservation relevance such as peatlands. The proposed method is reproducible, automated and based on open-source tools satellite imagery.",

author = "Hill, {Jane Katharine} and Mailys Lopes and Pierre-Louis Frison and Merry Crowson and Warren-Thomas, {Eleanor May} and Bambang Hariyadi and Kartika, {Winda D.} and Fahmuddin Agus and Hamer, {Keith C.} and Stringer, {Lindsay C.} and Nathalie Pettorelli",

note = "{\textcopyright} 2020 British Ecological Society. This is an author-produced version of the published paper. Uploaded in accordance with the publisher{\textquoteright}s self-archiving policy. Further copying may not be permitted; contact the publisher for details.",

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Hill, JK, Lopes, M, Frison, P-L, Crowson, M, Warren-Thomas, EM, Hariyadi, B, Kartika, WD, Agus, F, Hamer, KC, Stringer, LC & Pettorelli, N 2020, 'Improving the accuracy of land cover classiﬁcation in cloud persistent areas using optical and radar satellite image time series', Methods in ecology and evolution, vol. 11, no. 4, pp. 532-541. https://doi.org/10.1111/2041-210X.13359

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T1 - Improving the accuracy of land cover classiﬁcation in cloud persistent areas using optical and radar satellite image time series

AU - Hill, Jane Katharine

AU - Lopes, Mailys

AU - Frison, Pierre-Louis

AU - Crowson, Merry

AU - Warren-Thomas, Eleanor May

AU - Hariyadi, Bambang

AU - Kartika, Winda D.

AU - Agus, Fahmuddin

AU - Hamer, Keith C.

AU - Stringer, Lindsay C.

AU - Pettorelli, Nathalie

N1 - © 2020 British Ecological Society. This is an author-produced version of the published paper. Uploaded in accordance with the publisher’s self-archiving policy. Further copying may not be permitted; contact the publisher for details.

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N2 - The recent availability of high spatial and temporal resolution optical and radar satellite imagery has dramatically increased opportunities for mapping land cover at fine scales. Fusion of optical and radar images has been found useful in tropical areas affected by cloud cover because of their complementarity. However, the multitemporal dimension these data now offer is often neglected because these areas are primarily characterized by relatively low levels of seasonality and because the consideration of multitemporal data requires more processing time. Hence, land cover mapping in these regions is often based on imagery acquired for a single date or on an average of multiple dates.The aim of this work is to assess the added value brought by the temporal dimension of optical and radar time series when mapping land cover in tropical environments. Specifically, we compared the accuracies of classifications based on (a) optical time series, (b) their temporal average, (c) radar time series, (d) their temporal average, (e) a combination of optical and radar time series and (f) a combination of their temporal averages for mapping land cover in Jambi province, Indonesia, using Sentinel-1 and Sentinel-2 imagery.Using the full information contained in the time series resulted in significantly higher classification accuracies than using temporal averages (+14.7% for Sentinel-1, +2.5% for Sentinel-2 and +2% combining Sentinel-1 and Sentinel-2). Overall, combining Sentinel-2 and Sentinel-1 time series provided the highest accuracies (Kappa = 88.5%).Our study demonstrates that preserving the temporal information provided by satellite image time series can significantly improve land cover classifications in tropical biodiversity hotspots, improving our capacity to monitor ecosystems of high conservation relevance such as peatlands. The proposed method is reproducible, automated and based on open-source tools satellite imagery.

AB - The recent availability of high spatial and temporal resolution optical and radar satellite imagery has dramatically increased opportunities for mapping land cover at fine scales. Fusion of optical and radar images has been found useful in tropical areas affected by cloud cover because of their complementarity. However, the multitemporal dimension these data now offer is often neglected because these areas are primarily characterized by relatively low levels of seasonality and because the consideration of multitemporal data requires more processing time. Hence, land cover mapping in these regions is often based on imagery acquired for a single date or on an average of multiple dates.The aim of this work is to assess the added value brought by the temporal dimension of optical and radar time series when mapping land cover in tropical environments. Specifically, we compared the accuracies of classifications based on (a) optical time series, (b) their temporal average, (c) radar time series, (d) their temporal average, (e) a combination of optical and radar time series and (f) a combination of their temporal averages for mapping land cover in Jambi province, Indonesia, using Sentinel-1 and Sentinel-2 imagery.Using the full information contained in the time series resulted in significantly higher classification accuracies than using temporal averages (+14.7% for Sentinel-1, +2.5% for Sentinel-2 and +2% combining Sentinel-1 and Sentinel-2). Overall, combining Sentinel-2 and Sentinel-1 time series provided the highest accuracies (Kappa = 88.5%).Our study demonstrates that preserving the temporal information provided by satellite image time series can significantly improve land cover classifications in tropical biodiversity hotspots, improving our capacity to monitor ecosystems of high conservation relevance such as peatlands. The proposed method is reproducible, automated and based on open-source tools satellite imagery.

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DO - 10.1111/2041-210X.13359

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