Nov 21, 2024  
2024-2025 Undergraduate Academic Catalog-June 
    
2024-2025 Undergraduate Academic Catalog-June
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ELE 3701 - Control Systems

3 lecture hours 2 lab hours 4 credits
Course Description
This course introduces the modeling, analysis, and control of dynamic systems. The dynamic systems studied throughout this course include mechanical translational, mechanical rotational, and electromechanical. Control systems topics include deriving transfer functions for various dynamic systems, using transfer functions to analyze the expected output response to a given input, and designing closed loop controllers to achieve specified performance characteristics. These characteristics include transient response, stability criteria, and steady state error. The controller designs will be based on classical (e.g., PID compensator design) and modern (e.g., state variable feedback) design techniques. The laboratory work includes modeling, analysis, and controller design of dynamic systems. 
Prereq: ELE 2011 , MTH 2140  (quarter system prereq: EE 2070 or EE 3002B or EE 2725, MA 235 or MA 3502, MA 383)
Note: None
This course meets the following Raider Core CLO Requirement: None
Course Learning Outcomes
Upon successful completion of this course, the student will be able to:
  • Describe the basic components of mechanical and electrical systems
  • Formulate mechanical, electrical, and mixed discipline systems into appropriate differential equation models, including state space models
  • Recognize the similarity of the response characteristics of various physically dissimilar systems
  • Analyze a system’s time-domain performance
  • Determine system stability
  • Determine steady-state error in a system for typical inputs, including a disturbance input
  • Obtain the root-locus for typical open-loop transfer functions
  • Design closed-loop PID control systems
  • Design a state-feedback controller for a system in state-space representation

Prerequisites by Topic
  • Linear differential equation solution techniques
  • Transient analysis of first and second order systems (such as series and parallel RLC circuits)
  • Laplace transform analysis of circuits
  • Transfer functions
  • Electric circuit frequency response
  • Draw free body diagrams for static systems
  • Identify forces related to each other through Newton’s 3rd law of motion
  • Apply the principles of conservation of energy and conservation of linear momentum to solve problems

Course Topics
  • Modeling in the frequency domain
  • Modeling in the time domain
  • Time response analysis given a specific input
  • Block diagram system analysis
  • Stability analysis
  • Steady-state error analysis
  • Root-locus analysis
  • State-space analysis: conversions to and from transfer functions, stability, and steady-state error
  • State variable feedback controller design

Laboratory Topics
  • Introduction to data acquisition and real-time control hardware
  • System modeling using time-domain measurements
  • Feedback system simulation
  • Position feedback control design project
  • Velocity feedback control design project
  • State-space control

Coordinator
Dr. Jennifer L. Bonniwell



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