Home » Deep Learning-Based Forward Modeling and Inversion Techniques for Computational Physics Problems
Product Image

Deep Learning-Based Forward Modeling and Inversion Techniques for Computational Physics Problems

Yinpeng Wang | Qiang Ren
€59.99
Quantity:
In stock with our UK publisher. 14-28 days
Delivery/Collection within 10-20 working days
14 days return policy Shipping & Delivery
A01=Qiang Ren
A01=Yinpeng Wang
Author_Qiang Ren
Author_Yinpeng Wang
Average MSE
Category=PBKS
Category=PBW
Category=PH
Category=UB
Category=UY
Commercial Software COMSOL
Computational Physics
convolutional LSTM models
Data Set
deep learning for physical simulations
Digital Filtered Method
Dl Framework
electromagnetic inverse scattering
electromagnetics
Electronics and Information Engineering
Em Scattering
eq_bestseller
eq_computing
eq_isMigrated=1
eq_isMigrated=2
eq_nobargain
eq_non-fiction
eq_science
FDM
Fem Solver
graduate level computational science
Heat Conduction Matrix
Heat Conduction Problem
Heat Conduction System
Heat Flux
Heat Flux Load
Heat Flux Sensor
IHCP
Inverse Design
inverse problem solving
multi physics
physics-informed neural networks
Predicted Heat Flux
Resistive Random Access Memory
SFSM
Solve Heat Conduction Problems
Steady State Heat Conduction
Steady State Heat Conduction Problem
thermal conductivity estimation
thermology
Thermophysical Parameters
Unknown Heat Flux

Product details

  • ISBN 9781032503035
  • Weight: 358g
  • Dimensions: 156 x 234mm
  • Publication Date: 30 Jan 2025
  • Publisher: Taylor & Francis Ltd
  • Publication City/Country: GB
  • Product Form: Paperback
Secure checkout Fast Shipping Easy returns
Description

This book investigates in detail the emerging deep learning (DL) technique in computational physics, assessing its promising potential to substitute conventional numerical solvers for calculating the fields in real-time. After good training, the proposed architecture can resolve both the forward computing and the inverse retrieve problems.

Pursuing a holistic perspective, the book includes the following areas. The first chapter discusses the basic DL frameworks. Then, the steady heat conduction problem is solved by the classical U-net in Chapter 2, involving both the passive and active cases. Afterwards, the sophisticated heat flux on a curved surface is reconstructed by the presented Conv-LSTM, exhibiting high accuracy and efficiency. Additionally, a physics-informed DL structure along with a nonlinear mapping module are employed to obtain the space/temperature/time-related thermal conductivity via the transient temperature in Chapter 4. Finally, in Chapter 5, a series of the latest advanced frameworks and the corresponding physics applications are introduced.

As deep learning techniques are experiencing vigorous development in computational physics, more people desire related reading materials. This book is intended for graduate students, professional practitioners, and researchers who are interested in DL for computational physics.
About Qiang Ren | Yinpeng Wang

Yinpeng Wang received the B.S. degree in Electronic and Information Engineering from Beihang University, Beijing, China in 2020, where he is currently pursuing his M.S. degree in Electronic Science and Technology. Mr. Wang focuses on the research of electromagnetic scattering, inverse scattering, heat transfer, computational multi-physical fields, and deep learning.

Qiang Ren received the B.S. and M.S. degrees both in electrical engineering from Beihang University, Beijing, China, and Institute of Acoustics, Chinese Academy of Sciences, Beijing, China in 2008 and 2011, respectively, and the PhD degree in Electrical Engineering from Duke University, Durham, NC, in 2015. From 2016 to 2017, he was a postdoctoral researcher with the Computational Electromagnetics and Antennas Research Laboratory (CEARL) of the Pennsylvania State University, University Park, PA. In September 2017, he joined the School of Electronics and Information Engineering, Beihang University as an "Excellent Hundred" Associate Professor.

More from this author