Showing total 2 results

1. End-to-End Prediction of Lightning Events from Geostationary Satellite Images.

Author

Brodehl, Sebastian, Müller, Richard, Schömer, Elmar, Spichtinger, Peter, and Wand, Michael

Subjects

*REMOTE-sensing images, *ARTIFICIAL neural networks, *GEOSTATIONARY satellites, *THUNDERSTORMS, *INFRARED imaging, *CONVOLUTIONAL neural networks, *OPTICAL flow

Abstract

While thunderstorms can pose severe risks to property and life, forecasting remains challenging, even at short lead times, as these often arise in meta-stable atmospheric conditions. In this paper, we examine the question of how well we could perform short-term (up to 180 min) forecasts using exclusively multi-spectral satellite images and past lighting events as data. We employ representation learning based on deep convolutional neural networks in an "end-to-end" fashion. Here, a crucial problem is handling the imbalance of the positive and negative classes appropriately in order to be able to obtain predictive results (which is not addressed by many previous machine-learning-based approaches). The resulting network outperforms previous methods based on physically based features and optical flow methods (similar to operational prediction models) and generalizes across different years. A closer examination of the classifier performance over time and under masking of input data indicates that the learned model actually draws most information from structures in the visible spectrum, with infrared imaging sustaining some classification performance during the night. [ABSTRACT FROM AUTHOR]

Published

2022

2. DR-Net: An Improved Network for Building Extraction from High Resolution Remote Sensing Image.

Author

Chen, Meng, Wu, Jianjun, Liu, Leizhen, Zhao, Wenhui, Tian, Feng, Shen, Qiu, Zhao, Bingyu, and Du, Ruohua

Subjects

*REMOTE sensing, *CONVOLUTIONAL neural networks, *ARTIFICIAL neural networks, *BUILDING performance

Abstract

At present, convolutional neural networks (CNN) have been widely used in building extraction from remote sensing imagery (RSI), but there are still some bottlenecks. On the one hand, there are so many parameters in the previous network with complex structure, which will occupy lots of memories and consume much time during training process. On the other hand, low-level features extracted by shallow layers and abstract features extracted by deep layers of artificial neural network cannot be fully fused, which leads to an inaccurate building extraction from RSI. To alleviate these disadvantages, a dense residual neural network (DR-Net) was proposed in this paper. DR-Net uses a deeplabv3+Net encoder/decoder backbone, in combination with densely connected convolution neural network (DCNN) and residual network (ResNet) structure. Compared with deeplabv3+net (containing about 41 million parameters) and BRRNet (containing about 17 million parameters), DR-Net contains about 9 million parameters; So, the number of parameters reduced a lot. The experimental results for both the WHU Building Dataset and Massachusetts Building Dataset, DR-Net show better performance in building extraction than other two state-of-the-art methods. Experiments on WHU building data set showed that Intersection over Union (IoU) increased by 2.4% and F1 score increased by 1.4%; in terms of Massachusetts Building Dataset, IoU increased by 3.8% and F1 score increased by 2.9%. [ABSTRACT FROM AUTHOR]

Published

2021