Introduces the mathematical techniques for determining the behavior of analog systems. Topics include complex numbers and functions, first and second order differential equations for modeling electrical and mechanical systems, the Laplace transform, solutions for initial conditions, solutions for a step input, general transient response, the frequency response, Bode plots, s-plane analysis and stability, one and two pole filters, the Fourier transform. Weekly hours: 3 Lecture hours and 2 Practicum/Lab hoursPrerequisite(s): EP 202.3 or GE 153.2. Prerequisite(s) or Corequisite(s): MATH 224.3 or MATH 226.3 or MATH 238.3. Note: Students who have credit for EE 214 may not take this course for credit.
Introduces the mathematical techniques for determining the behavior of analog systems. Topics include complex numbers and functions, first and second order differential equations for modeling electrical and mechanical systems, the Laplace transform, solutions for initial conditions, solutions for a step input, general transient response, the frequency response, Bode plots, s-plane analysis and stability, one and two pole filters, the Fourier transform. Weekly hours: 3 Lecture hours and 2 Practicum/Lab hoursPrerequisite(s): EP 202.3 or GE 153.2. Prerequisite(s) or Corequisite(s): MATH 224.3 or MATH 226.3 or MATH 238.3. Note: Students who have credit for EE 214 may not take this course for credit.
