| ²é¿´: 364 | »Ø¸´: 3 | |||
| ¡¾½±Àø¡¿ ±¾Ìû±»ÆÀ¼Û1´Î£¬×÷ÕßhuishouzhongÔö¼Ó½ð±Ò 0.4 ¸ö | |||
| µ±Ç°Ö»ÏÔʾÂú×ãÖ¸¶¨Ìõ¼þµÄ»ØÌû£¬µã»÷ÕâÀï²é¿´±¾»°ÌâµÄËùÓлØÌû | |||
huishouzhongÌú¸Ëľ³æ (СÓÐÃûÆø)
|
[×ÊÔ´]
Machine Learning in Modeling and Simulation - Methods Applications
|
||
|
·ÖÏí¼ÆËãÁ¦Ñ§´óÅ£klaus-j¨¹rgen batheºÍtimon rabczukÔÚ2023ÄêбàµÄÊ飺 machine learning in modeling and simulation methods and applications  Á½Î»´óÅ£µÄÒýÓôÎÊý£º  ---------  Ç°ÑÔ½ÚÑ¡£º our objective in this book is to present ml techniques for computer-aided engineering with a focus on the fundamental theoretical ingredients and the exciting use of ml in the next generation of computational methods for modeling and simulation. an impressive example of ml in engineering is the emergence and great potential of using digital twins for design and monitoring of structures, with the word ¡°structures¡± interpreted to include not only traditional structures, like buildings, dams, and bridges, but also biological, offshore, electromagnetic, turbines, nuclear, and many other structures. we foresee here major and widely spread applications. the book consists of 12 chapters focusing on machine learning in modeling and simulation, starting with an extensive overview of concepts and applications in chap. 1. the following two chapters provide a historical and theoretical overview¡ªincluding implementation details¡ªof two very popular machine learning approaches: artificial neural networks and gaussian processes. the remainder of the book focuses on the use of ml techniques to solve specific problems in engineering, physics or materials science starting with data-driven model discovery followed by physics-informed neural networks that may become a powerful alternative to classical discretization methods such as finite elements. namely, the networks allow the solution of partial differential equations while also incorporating experimentaldata. physics-informeddeepneuraloperatorscanbeseenasanimprovement and have the potential of solving not only one specific problem but any problem in a large class of problems. the next chapters focus on important topics regarding digital twins, reduced order modeling, regression models and the valuable use of ml in topology optimization methodologies. the last two chapters of the book focus on the design of new materials. the first approach is data-driven while the second approach takes advantage of interatomic potentials in the context of hierarchical multiscale modeling. these ml approaches have the potential to significantly widen the possibilities and accelerate the design of new materials. the work on this book has been very exciting, and we greatly thank all authors and co-authors of the book chapters. their valuable contributions, dedicated work, and great cooperation made it possible to complete this book in a timely manner. weimar, germany timon rabczuk cambridge, usa klaus-j¨¹rgen bathe december 2022 |
»Ø¸´´ËÂ¥» ±¾Ìû¸½¼þ×ÊÔ´Áбí
-
»¶Ó¼à¶½ºÍ·´À¡£ºÐ¡Ä¾³æ½öÌṩ½»Á÷ƽ̨£¬²»¶Ô¸ÃÄÚÈݸºÔð¡£
±¾ÄÚÈÝÓÉÓû§×ÔÖ÷·¢²¼£¬Èç¹ûÆäÄÚÈÝÉæ¼°µ½ÖªÊ¶²úȨÎÊÌ⣬ÆäÔðÈÎÔÚÓÚÓû§±¾ÈË£¬Èç¶Ô°æȨÓÐÒìÒ飬ÇëÁªÏµÓÊÏ䣺libolin3@tal.com - ¸½¼þ 1 : 2023_Machine_Learning_in_Modeling_and_Simulation.pdf
2024-04-15 15:53:25, 12.76 M
» ÊÕ¼±¾ÌûµÄÌÔÌùר¼ÍƼö
 ÊýÖµ·ÂÕæËã·¨Êé¼® |
» ±¾ÌûÒÑ»ñµÃµÄºì»¨£¨×îÐÂ10¶ä£©
cl1207» ²ÂÄãϲ»¶
C¿ÚʳƷ
ÒѾÓÐ13È˻ظ´
-
ÕâÑùµÄ¿ÎÌâ×éÖµµÃÈ¥Âð
ÒѾÓÐ7È˻ظ´
-
¹«ÅɳöȥҪ׼±¸¶àÉÙÇ®£¿
ÒѾÓÐ6È˻ظ´
-
ÎÒÃÇѧԺ³£Äêλ¾Ó ¸÷ѧԺ µ¹ÊýµÚ¶þ¡£×¨Òµ³·ÏúµÄ»°£¬ÔÚ±àÕßÓÐʲô²¹³¥£¿
ÒѾÓÐ5È˻ظ´
-
»¹ÄܶÁÉϲ©Ê¿Âð
ÒѾÓÐ11È˻ظ´
-
ǰЩÌ쿪»áÓиöÈ˼ûµ½È˾͸ã¹Øϵ£¬Ò»²é´ËÈËÈ«ÊÇMDPI/HindawiÂÛÎÄ£¬±ÉÊÓ!
ÒѾÓÐ53È˻ظ´
-
½ñÄêÏã½³õÉó³ö½á¹ûÁËÂð
ÒѾÓÐ11È˻ظ´
-
ÇëÎÊÆÀÉóר¼Òҽѧ¿Ú½ñÄ꺯ÉóÊÇÄÄÌì½áÊøµÄ£¿
ÒѾÓÐ13È˻ظ´
-
Éó¸å½»Á÷
ÒѾÓÐ6È˻ظ´
-
ÃÀ¹ú¶Ô»ªÎªµÄÖƲûáÓ°ÏìÓ¢ÎÄÂÛÎÄ·¢±íÂð
ÒѾÓÐ8È˻ظ´
4Â¥2024-05-09 09:12:42
50