The research direction has the following main applications:
1. engineering design and optimization: through the simulation software, engineers can carry out simulation experiments of various coupling systems in the system design stage to evaluate the performance of different design schemes and optimize the system structure and technology.
2. Performance evaluation and prediction: Simulation software can be used to simulate and evaluate the performance of the system in actual operation, such as the strength and stability of buildings, the dynamic performance of vehicles, fuel efficiency, etc., so as to help decision makers make accurate decisions.
3. Fault diagnosis and correction: The fault of the coupling system may be the result of the interaction of multi-disciplinary factors, and the simulation software can simulate and identify the fault causes of the system and correct the system.
4. Understanding and exploring physical phenomena: Coupled system simulation software provides a method to explore and understand complex physical phenomena, such as earthquakes, floods and storms. Simulation can simulate these phenomena and provide valuable information for academic research and practical application.
However, to achieve effective coupling, system simulation software needs enough interdisciplinary knowledge, including knowledge in mathematics, physics, engineering, computer science and other fields. In addition, this field is also facing the challenge of computing resources, because simulating complex systems usually requires a lot of computing resources and time.
Generally speaking, the research direction of structural multidisciplinary coupling system simulation software and its application has broad application prospects and challenges, and has great potential in solving complex problems and optimizing system performance.