系統動力學課程介紹了一套統一的系統建模和分析概念和技術,針對機械運動、電路等工程領域。建模技術使用基於能量的狀態空間方法並提供與系統表示的連結。採用這種方法可以獲得一組描述物理系統動態或時變行為的常微分方程式。確定動態響應可以進一步提供透過修改系統結構和參數來改善系統性能的策略。通用方法論可以擴展到經濟學、生物學、生態學、社會科學和醫學等非工程系統。The system power learning course introduces a set of unified system modeling and analysis concepts and techniques, and points out engineering fields such as mechanical movement and circuits. Modeling techniques use energy-based state space methods and provide a link to system representation. Using this method, you can obtain an ordinary differential equation that describes the dynamic or time-changing behavior of a physical system. Confirmation that dynamic responses should further provide strategies to improve system performance by modifying system structures and parameters. General methodologies can be expanded to non-engineering systems such as economy, biology, ecology, social sciences, and medicine.
1.自動控制系統(Automatic Control Systems-Farid Golnaraghi, Benjamin C. Kuo)第十版江昭皚、江秉軒-(東華)
2.Automatic Control Systems, 10th Edition, F. Golnaraghi, and B. C. Kuo, H. Wiliey & Sons, Inc,2010
1. Automatic Control Systems-Farid Golnaraghi, Benjamin C. Kuo, Jiang Bing--(Tonghua)
2. Automatic Control Systems, 10th Edition, F. Golnaraghi, and B. C. Kuo, H. Wiliey & Sons, Inc, 2010
| 評分項目 Grading Method | 配分比例 Grading percentage | 說明 Description |
|---|---|---|
| 平時成績平時成績 Regular achievements |
35 | 含作業成績及平常考 |
| 期中考期中考 Midterm exam |
30 | |
| 期末考期末考 Final exam |
30 | |
| 出席及其他出席及其他 Attendance and other |
5 |
