Analyzing and design of control systems with performance evaluation. Distinguish between time domain and frequency domain specifications. Demonstrate effect of lead compensator in time domain. Identify aspects of lag compensation in time domain. Show the differences between lag and lead compensators versus lead-lag compensators. Demonstrate effect of lead compensator in frequency domain. Demonstrate effect of lag compensator in frequency domain. Explain the role of matrix manipulation and linear differential equations for control systems representation. Defining control system representation techniques (phase variable form, diagonal form, …etc.). Show how to solve the state equation. Define state transition matrix. Define controllability problem. Define observability problem. Distinguish the role of controllability / uncontrollability criterion for pole placement. Showing the basic structure of a digital control system. Definition and properties of Z-transform. Knowing open and closed loop transfer s. Distinguish between open loop and closed loop responses in presence of sampler. Associate the choice of pole location with digital control systems stability criterion.
Bachelor Degree in Mechanical Engineering (Mechatronics Engineering)
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| content serial | Description |
|---|---|
| 1 | Lead compensation design. |
| 2 | Lag compensation design. |
| 3 | Lag-Lead compensation design. |
| 4 | Lead compensation by frequency response. |
| 5 | Lag compensation by frequency response. |
| 6 | Introduction to state-space. |
| 7 | 7th week exam + Methods of state space representation. |
| 8 | Solution of state equation. |
| 9 | Controllability – observability. |
| 10 | State variable feedback. |
| 11 | Introduction to digital control systems. |
| 12 | 12th week exam + The Z-transform. |
| 13 | Block diagram of digital systems. |
| 14 | Time response of digital systems. |
| 15 | Stability analysis for digital systems. |
| 16 | Final Exam. |
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