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Previously offered as ChE
494/561 |
| Meets on Campus |
Also available via the Internet through ASUEngineeringOnline.com |
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| Instructor: |
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| Prerequisites: |
| Undergraduate controls course or equivalent from any engineering discipline. Knowledge of basic linear algebra and complex number arithmetic is desirable. Prior experience with MATLAB/SIMULINK is helpful but not required. |
| Textbooks: |
The course will make substantial use of class and presentation notes developed by the instructor. The following texts are recommended: B.A. Ogunnaike and W.H. Ray, 1994, Process Dynamics, Modeling, and Control, Oxford University Press, ISBN 0-19-509119-1. D.E. Seborg, T.F. Edgar, & D.A. Mellichamp, 2004, Process Dynamics and Control, 2nd edition, Wiley and Sons, ISBN 0-471-00077-9. Morari, M. and E. Zafiriou,
1987, Robust Process Control, Prentice-Hall, ISBN 0-13-782153-0. |
| Course Objectives: |
| The course introduces students to advanced process control concepts with emphasis on methods and techniques with significant impact on industrial practice. Homework assignments are highly design-oriented and rely on MATLAB w/SIMULINK to provide students with a "hands-on" experience on the course material. |
| Course Description: |
| The course presents a wide variety of concepts and techniques for designing process control systems that extend beyond the standard classical feedback/PID tuning methods that form part of a typical undergraduate course. Advanced analog single loop control, digital (computer) control, and multivariable control analysis and design procedures are presented. These include: 1) a detailed presentation of the Internal Model Control design procedure for both continuous-time (analog) and discrete-time (digital) control systems, 2) how to make single-loop designs work in a multivariable system through the judicious design of decentralized and decoupled control systems, and 3) the design of control systems for constrained multivariable processes via Model Predictive Control. The application of these ideas to problems that are not viewed as traditional process control problems (specifically, enterprise systems and supply chain management) will be presented. A brief overview of system identification techniques in support of advanced control system design will also be discussed, as time permits. |
| Course Requirements:
Homework: 6-8 problem sets (total) . Examinations: One in-class 75 minute exam, one two-hour final. Computer Facilities: Students must have access to MATLAB with SIMULINK and the Control System, Signal Processing, and Model Predictive Control toolboxes. Laboratory and Projects: There is no laboratory associated with
this course. Students may be required to perform a small project
on a topic of industrial or research interest. |
| Course Outline by Topical Areas:
I. Modeling and Systems Overview (1.5 weeks) A.Dynamic modeling via conservation and accounting principles II. Analysis and design of analog SISO closed-loop systems (3 weeks) A. Objectives of feedback control; H_2 and H_infinity optimality
criteria VII. Analysis and design of digital SISO closed-loop systems (3 weeks) A. Representation of discrete-time systems via z-transforms. IV. Multi-input, multi-output systems (3 weeks) A. Variable selection and pairing for decentralized control. V. Model Predictive Control (3.5 weeks) A. Moving horizon philosophy and state-space formulation of
MPC VI. System Identification Overview (1 week) |
| Additional Information: |
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