Scale Sequence Joint Deep Learning (SS-JDL) for land use and land cover classification
Scale Sequence Joint Deep Learning (SS-JDL) for land use and land cover classification
Choosing appropriate scales for remotely sensed image classification is extremely important yet still an open question in relation to deep convolutional neural networks (CNN), due to the impact of spatial scale (i.e., input patch size) on the recognition of ground objects. Currently, the optimal scale selection processes are extremely cumbersome and time-consuming requiring repetitive experiments involving trial-and-error procedures, which significantly reduce the practical utility of the corresponding classification methods. This issue is crucial when trying to classify large-scale land use (LU) and land cover (LC) jointly (Zhang et al., 2019). In this paper, a simple and parsimonious Scale Sequence Joint Deep Learning (SS-JDL) method is proposed for joint LU and LC classification, in which a sequence of scales is embedded in the iterative process of fitting the joint distribution implicit in the joint deep learning (JDL) method, thus, replacing the previous paradigm of scale selection. The sequence of scales, derived autonomously and used to define the CNN input patch sizes, provides consecutive information transmission from small-scale features to large-scale representations, and from simple LC states to complex LU characterisations. The effectiveness of the novel SS-JDL method was tested on aerial digital photography of three complex and heterogeneous landscapes, two in Southern England (Bournemouth and Southampton) and one in North West England (Manchester). Benchmark comparisons were provided in the form of a range of LU and LC methods, including the state-of-the-art joint deep learning (JDL) method. The experimental results demonstrated that the SS-JDL consistently outperformed all of the state-of-the-art baselines in terms of both LU and LC classification accuracies, as well as computational efficiency. The proposed SS-JDL method, therefore, represents a fast and effective implementation of the state-of-the-art JDL method. By creating a single, unifying joint distribution framework for classifying higher order feature representations, including LU, the SS-JDL method has the potential to transform the classification paradigm in remote sensing, and in machine learning more generally.
Convolutional neural network, Hierarchical representations, Joint classification, Multi-scale deep learning, Optimal scale selection
Zhang, Ce
72e137e7-06c5-483e-bdc7-21629e03bb5b
Harrison, Paula A.
8fe8e681-0605-4b41-9581-2f2687a4a603
Pan, Xin
387a1d0d-63a4-432a-a443-0654cfcc9321
Li, Huapeng
9e72ecd5-9964-4038-ab71-9bc7a2fb0510
Sargent, Isabel
3df2050d-b24e-4f60-bc6e-8b1fafdb3f5a
Atkinson, Peter M.
96e96579-56fe-424d-a21c-17b6eed13b0b
1 February 2020
Zhang, Ce
72e137e7-06c5-483e-bdc7-21629e03bb5b
Harrison, Paula A.
8fe8e681-0605-4b41-9581-2f2687a4a603
Pan, Xin
387a1d0d-63a4-432a-a443-0654cfcc9321
Li, Huapeng
9e72ecd5-9964-4038-ab71-9bc7a2fb0510
Sargent, Isabel
3df2050d-b24e-4f60-bc6e-8b1fafdb3f5a
Atkinson, Peter M.
96e96579-56fe-424d-a21c-17b6eed13b0b
Zhang, Ce, Harrison, Paula A., Pan, Xin, Li, Huapeng, Sargent, Isabel and Atkinson, Peter M.
(2020)
Scale Sequence Joint Deep Learning (SS-JDL) for land use and land cover classification.
Remote Sensing of Environment, 237, [111593].
(doi:10.1016/j.rse.2019.111593).
Abstract
Choosing appropriate scales for remotely sensed image classification is extremely important yet still an open question in relation to deep convolutional neural networks (CNN), due to the impact of spatial scale (i.e., input patch size) on the recognition of ground objects. Currently, the optimal scale selection processes are extremely cumbersome and time-consuming requiring repetitive experiments involving trial-and-error procedures, which significantly reduce the practical utility of the corresponding classification methods. This issue is crucial when trying to classify large-scale land use (LU) and land cover (LC) jointly (Zhang et al., 2019). In this paper, a simple and parsimonious Scale Sequence Joint Deep Learning (SS-JDL) method is proposed for joint LU and LC classification, in which a sequence of scales is embedded in the iterative process of fitting the joint distribution implicit in the joint deep learning (JDL) method, thus, replacing the previous paradigm of scale selection. The sequence of scales, derived autonomously and used to define the CNN input patch sizes, provides consecutive information transmission from small-scale features to large-scale representations, and from simple LC states to complex LU characterisations. The effectiveness of the novel SS-JDL method was tested on aerial digital photography of three complex and heterogeneous landscapes, two in Southern England (Bournemouth and Southampton) and one in North West England (Manchester). Benchmark comparisons were provided in the form of a range of LU and LC methods, including the state-of-the-art joint deep learning (JDL) method. The experimental results demonstrated that the SS-JDL consistently outperformed all of the state-of-the-art baselines in terms of both LU and LC classification accuracies, as well as computational efficiency. The proposed SS-JDL method, therefore, represents a fast and effective implementation of the state-of-the-art JDL method. By creating a single, unifying joint distribution framework for classifying higher order feature representations, including LU, the SS-JDL method has the potential to transform the classification paradigm in remote sensing, and in machine learning more generally.
Text
SSJDL_manuscript_Ce_accepted (1)
- Accepted Manuscript
More information
Accepted/In Press date: 2 December 2019
e-pub ahead of print date: 13 December 2019
Published date: 1 February 2020
Keywords:
Convolutional neural network, Hierarchical representations, Joint classification, Multi-scale deep learning, Optimal scale selection
Identifiers
Local EPrints ID: 437308
URI: http://eprints.soton.ac.uk/id/eprint/437308
ISSN: 0034-4257
PURE UUID: 6e3ee3f9-82d6-47c1-8410-65dcf84ff260
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Date deposited: 24 Jan 2020 17:30
Last modified: 17 Mar 2024 05:14
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Contributors
Author:
Ce Zhang
Author:
Paula A. Harrison
Author:
Xin Pan
Author:
Huapeng Li
Author:
Isabel Sargent
Author:
Peter M. Atkinson
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