TY - JOUR
T1 - Domain-Adapted Convolutional Networks for Satellite Image Classification
T2 - A Large-Scale Interactive Learning Workflow
AU - Lunga, Dalton
AU - Yang, Hsiuhan Lexie
AU - Reith, Andrew
AU - Weaver, Jeanette
AU - Yuan, Jiangye
AU - Bhaduri, Budhendra
N1 - Publisher Copyright:
© 2008-2012 IEEE.
PY - 2018/3
Y1 - 2018/3
N2 - Satellite imagery often exhibits large spatial extent areas that encompass object classes with considerable variability. This often limits large-scale model generalization with machine learning algorithms. Notably, acquisition conditions, including dates, sensor position, lighting condition, and sensor types, often translate into class distribution shifts introducing complex nonlinear factors and hamper the potential impact of machine learning classifiers. This paper investigates the challenge of exploiting satellite images using convolutional neural networks (CNN) for settlement classification where the class distribution shifts are significant. We present a large-scale human settlement mapping workflow based-off multiple modules to adapt a pretrained CNN to address the negative impact of distribution shift on classification performance. To extend a locally trained classifier onto large spatial extents areas we introduce several submodules: First, a human-in-the-loop element for relabeling of misclassified target domain samples to generate representative examples for model adaptation; second, an efficient hashing module to minimize redundancy and noisy samples from the mass-selected examples; and third, a novel relevance ranking module to minimize the dominance of source example on the target domain. The workflow presents a novel and practical approach to achieve large-scale domain adaptation with binary classifiers that are based-off CNN features. Experimental evaluations are conducted on areas of interest that encompass various image characteristics, including multisensors, multitemporal, and multiangular conditions. Domain adaptation is assessed on source-target pairs through the transfer loss and transfer ratio metrics to illustrate the utility of the workflow.
AB - Satellite imagery often exhibits large spatial extent areas that encompass object classes with considerable variability. This often limits large-scale model generalization with machine learning algorithms. Notably, acquisition conditions, including dates, sensor position, lighting condition, and sensor types, often translate into class distribution shifts introducing complex nonlinear factors and hamper the potential impact of machine learning classifiers. This paper investigates the challenge of exploiting satellite images using convolutional neural networks (CNN) for settlement classification where the class distribution shifts are significant. We present a large-scale human settlement mapping workflow based-off multiple modules to adapt a pretrained CNN to address the negative impact of distribution shift on classification performance. To extend a locally trained classifier onto large spatial extents areas we introduce several submodules: First, a human-in-the-loop element for relabeling of misclassified target domain samples to generate representative examples for model adaptation; second, an efficient hashing module to minimize redundancy and noisy samples from the mass-selected examples; and third, a novel relevance ranking module to minimize the dominance of source example on the target domain. The workflow presents a novel and practical approach to achieve large-scale domain adaptation with binary classifiers that are based-off CNN features. Experimental evaluations are conducted on areas of interest that encompass various image characteristics, including multisensors, multitemporal, and multiangular conditions. Domain adaptation is assessed on source-target pairs through the transfer loss and transfer ratio metrics to illustrate the utility of the workflow.
KW - Adaptation model
KW - image classification
KW - remote sensing
KW - semi-supervised learning
KW - supervised learning
UR - http://www.scopus.com/inward/record.url?scp=85041519479&partnerID=8YFLogxK
U2 - 10.1109/JSTARS.2018.2795753
DO - 10.1109/JSTARS.2018.2795753
M3 - Article
AN - SCOPUS:85041519479
SN - 1939-1404
VL - 11
SP - 962
EP - 977
JO - IEEE Journal of Selected Topics in Applied Earth Observations and Remote Sensing
JF - IEEE Journal of Selected Topics in Applied Earth Observations and Remote Sensing
IS - 3
ER -