Nov 21, 2024  
2021-2022 Undergraduate Academic Catalog 
    
Catalog Navigation
  Catalog Home
  Academic Calendar
  University Overview
  Admissions Department
  Academic Regulations and Policies
  Student Financial Services
  Academic Departments, Undergraduate Degree Programs, Minors, and Certificates
  Degree Programs, Minors, and Certificates
  University Scholars Honors Program
  Reserve Officers’ Training Corps. (ROTC)
  English for Academic Purposes (EAP)
  Course Descriptions
  Administration, Board of Regents, Faculty, and Advisory Committees
  Campus Map
  Student Resources
  My Portfolio
HELP
2021-2022 Undergraduate Academic Catalog [ARCHIVED CATALOG]

Facebook this Page (opens a new window)
Tweet this Page (opens a new window)
Add to Portfolio (opens a new window)

EE 3051B - Dynamic Systems

4 lecture hours 0 lab hours 4 credits
Course Description
This course introduces modeling and analysis techniques of the major types of dynamic engineering systems: mechanical translational, mechanical rotational, thermal, electromechanical, fluid, and operational amplifier systems. Appropriate methods for analytically solving system differential equations are reviewed. (prereq: EE 3002B  or EE 2070 , PH 113  or PH 2011 ) (coreq: MA 383 )
Course Learning Outcomes
Upon successful completion of this course, the student will be able to:
  • Represent a mechanical system using free body diagrams
  • Understand basic components of dynamic mechanical and electrical systems
  • Combine mechanical and electrical (including DC motors) components into systems
  • Formulate mechanical, electrical, and mixed discipline systems into appropriate differential equation models including state space models
  • Analyze systems for dynamic time-domain response and for frequency response
  • Predict system response using analytic methods
Prerequisites by Topic
  • Linear differential equation solution techniques
  • Transient analysis of series and parallel RLC circuits
  • Laplace transform analysis of circuits
  • Transfer functions
  • Electric circuit frequency response
  • 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 translational and rotational dynamic systems in the time domain
  • Modeling translational and rotational dynamic systems in the frequency domain
  • Time response of 2nd order mechanical systems
  • State-space representation of systems
Coordinator
Dr. Jennifer Bonniwell


Facebook this Page (opens a new window)
Tweet this Page (opens a new window)
Add to Portfolio (opens a new window)