scholarly journals Can Deep Learning Extract Useful Information about Energy Dissipation and Effective Hydraulic Conductivity from Gridded Conductivity Fields?

2021 ◽  
Author(s):  
Mohammad Abdolhosseini Moghaddam ◽  
Ty Paul Andrew Ferré ◽  
Jeffrey Klakovich ◽  
Hoshin Vijay Gupta ◽  
Mohammad Reza Ehsani
Keyword(s):  
Deep Learning ◽  
Energy Dissipation ◽  
Hydraulic Conductivity ◽  
Learning Algorithm ◽  
High Fidelity ◽  
Effective Hydraulic Conductivity ◽  
Deep Learning Algorithm ◽  
Localized Structures ◽  
Hydrologic Systems ◽  
Controlled Flow

We confirm that energy dissipation weighting provides the most accurate approach to determining the effective hydraulic conductivity (Keff) of a binary K grid. A deep learning algorithm (UNET) can infer Keff with extremely high accuracy (R2 > 0.99). The UNET architecture could be trained to infer the energy dissipation weighting pattern from an image of the K distribution with high fidelity, although it was less accurate for cases with highly localized structures that controlled flow. Furthermore, the UNET architecture learned to infer the energy dissipation weighting even if it was not trained on this information directly. However, the weights were represented within the UNET in a way that was not immediately interpretable by a human user. This reiterates the idea that even if ML/DL algorithms are trained to make some hydrologic predictions accurately, they must be designed and trained to provide each user-required output if their results are to be used to improve our understanding of hydrologic systems most effectively.

scholarly journals Can Deep Learning Extract Useful Information about Energy Dissipation and Effective Hydraulic Conductivity from Gridded Conductivity Fields?

Water ◽  
2021 ◽  
Vol 13 (12) ◽  
pp. 1668
Author(s):  
Mohammad Moghaddam ◽  
Paul A Ferre ◽  
Mohammad Reza Ehsani ◽  
Jeffrey Klakovich ◽  
Hoshin Vijay Gupta
Keyword(s):  
Deep Learning ◽  
Energy Dissipation ◽  
Hydraulic Conductivity ◽  
Learning Algorithm ◽  
High Accuracy ◽  
Effective Hydraulic Conductivity ◽  
Deep Learning Algorithm ◽  
Localized Structures ◽  
Hydrologic Systems ◽  
Controlled Flow

We confirm that energy dissipation weighting provides the most accurate approach to determining the effective hydraulic conductivity (Keff) of a binary K grid. A deep learning algorithm (UNET) can infer Keff with extremely high accuracy (R2 > 0.99). The UNET architecture could be trained to infer the energy dissipation weighting pattern from an image of the K distribution, although it was less accurate for cases with highly localized structures that controlled flow. Furthermore, the UNET architecture learned to infer the energy dissipation weighting even if it was not trained directly on this information. However, the weights were represented within the UNET in a way that was not immediately interpretable by a human user. This reiterates the idea that even if ML/DL algorithms are trained to make some hydrologic predictions accurately, they must be designed and trained to provide each user-required output if their results are to be used to improve our understanding of hydrologic systems.

Deep learning of virtual-based aerial images: increasing the fidelity of serious games for live training

2019 ◽  
Author(s):  
Dean Reed ◽  
Troyle Thomas ◽  
Shane Reynolds ◽  
Jonathan Hurter ◽  
Latika Eifert
Keyword(s):  
Deep Learning ◽  
Serious Games ◽  
Learning Algorithm ◽  
Military Training ◽  
Aerial Imagery ◽  
Aerial Images ◽  
High Fidelity ◽  
Natural Environments ◽  
Game Engine ◽  
Deep Learning Algorithm

The aim of rapidly reconstructing high-fidelity, Synthetic Natural Environments (SNEs) may benefit from a deep learning algorithm: this paper explores how deep learning on virtual, or synthetic, terrain assets of aerial imagery can support the process of quickly and effectively recreating lifelike SNEs for military training, including serious games. Namely, a deep learning algorithm was trained on small hills, or berms, from a SNE, derived from real-world geospatial data. In turn, the deep learning algorithm’s level of classification was tested. Then, assets learned (i.e., classified) from the deep learning were transferred to a game engine for reconstruction. Ultimately, results suggest that deep learning will support automated population of highfidelity SNEs. Additionally, we identify constraints and possible solutions when utilising the commercial game engine of Unity for dynamic terrain generation.

scholarly journals Study on Radar Echo-Filling in an Occlusion Area by a Deep Learning Algorithm

2021 ◽  
Vol 13 (9) ◽  
pp. 1779
Author(s):  
Xiaoyan Yin ◽  
Zhiqun Hu ◽  
Jiafeng Zheng ◽  
Boyong Li ◽  
Yuanyuan Zuo
Keyword(s):  
Deep Learning ◽  
Loss Function ◽  
Learning Algorithm ◽  
Weather Radar ◽  
Loss Functions ◽  
Training Dataset ◽  
Echo Intensity ◽  
Common Mean ◽  
Deep Learning Algorithm ◽  
Radar Beam

Radar beam blockage is an important error source that affects the quality of weather radar data. An echo-filling network (EFnet) is proposed based on a deep learning algorithm to correct the echo intensity under the occlusion area in the Nanjing S-band new-generation weather radar (CINRAD/SA). The training dataset is constructed by the labels, which are the echo intensity at the 0.5° elevation in the unblocked area, and by the input features, which are the intensity in the cube including multiple elevations and gates corresponding to the location of bottom labels. Two loss functions are applied to compile the network: one is the common mean square error (MSE), and the other is a self-defined loss function that increases the weight of strong echoes. Considering that the radar beam broadens with distance and height, the 0.5° elevation scan is divided into six range bands every 25 km to train different models. The models are evaluated by three indicators: explained variance (EVar), mean absolute error (MAE), and correlation coefficient (CC). Two cases are demonstrated to compare the effect of the echo-filling model by different loss functions. The results suggest that EFnet can effectively correct the echo reflectivity and improve the data quality in the occlusion area, and there are better results for strong echoes when the self-defined loss function is used.

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