BIBLIO is the largest independent book marketplace in the world, with over 100 million books.

Skip to content

High Performance Computing and Artificial Intelligence for Geosciences

High Performance Computing and Artificial Intelligence for Geosciences

High Performance Computing and Artificial Intelligence for Geosciences
Stock photo: cover may vary

High Performance Computing and Artificial Intelligence for Geosciences Hardback - 2023

by Wang, Yuzhu

Add to wish list
  • New
New

Description

new.
Ask the seller a question Add to wish list
A$139.36
A$5.79 Delivery within USA
Standard delivery: 2 to 14 days
More delivery options
Ships from GreatBookPrices (Maryland, United States)

Details

  • Title High Performance Computing and Artificial Intelligence for Geosciences
  • Author Wang, Yuzhu
  • Binding Hardback
  • Condition New
  • Pages 188
  • Volumes 1
  • Language ENG
  • Publisher Mdpi AG
  • Publication date 2023-07-20
  • Bookseller's Inventory # 46166441-n
  • ISBN 9783036581804 / 3036581804
  • Weight 1.34 lbs (0.61 kg)
  • Dimensions 9.61 x 6.69 x 0.63 in (24.41 x 16.99 x 1.60 cm)
  • Category Science
  • Quantity available 5

About GreatBookPrices Maryland, United States

Biblio member since 2024

Since 1991, we have worked every day to serve our customers with state-of-the-art technology and world class service. We are dedicated to providing customers around the world with the widest selection of books, DVDs, and CDs at the absolute lowest price.

Terms of Sale: 30 day return guarantee, with full refund including original shipping costs for up to 30 days after delivery if an item arrives misdescribed or damaged.

Browse books from GreatBookPrices

Reader reviews for High Performance Computing and Artificial Intelligence for Geosciences

From the publisher

In total, this Special Issue includes 11 papers. Firstly, Qi et al. conducted research on the large-scale non-uniform parallel solution of the two-dimensional Saint-Venant equations for flood behavior modeling. Zhang et al. proposed an efficient deep learning-based mineral identification method. Subsequently, Huang et al. proposed a named entity recognition method for geological news based on BERT model. Yang et al. proposed an automatic landslide identification method to solve the problem of the time-consuming nature and low efficiency of traditional landslide identification methods. Du et al. analyzed the potential of unsupervised machine learning methods for submarine landslide prediction. Wang et al. performed parallel computations on the inversion algorithm of the two-dimensional ZTEM. Xu et al. used the sliding window method and gray relational analysis to extract features from multi-source real-time monitoring data of landslides. Furthermore, Cao et al. proposed a new method called dual encoder transform (DualET) for the short-term prediction of photovoltaic power. Hao et al. conducted a series of parallel optimizations and large-scale parallel simulations on the high-resolution ocean model. Wang et al. proposed a time series prediction model for landslide displacements using mean-based low-rank autoregressive tensor completion. Finally, Yang et al. developed a measure of site-level gross primary productivity (GPP) using the GeoMAN model.

tracking-