Course: Computer-Aided Circuit Analysis and Design
Introduction: Overview of the necessity for computer-aided circuit analysis due to the complexity of circuits and lack of closed-form solutions.
Fundamental Concepts: Key theories and laws governing electronic circuits, including Kirchhoff's and Ohm's laws.
Network Equations: Techniques like nodal and mesh analysis for deriving and solving circuit equations, using matrix representations.
Modeling of Devices: Representation of resistors, capacitors, and inductors through impedance and admittance models in the time and frequency domains.
Design and Optimization: Using simulations to evaluate circuit stability, sensitivity, and optimize performance.
Solution Methods: Numerical approaches for solving circuits, including Gaussian elimination, LU decomposition, and MATLAB simulations for real-time circuit behavior analysis.
Tools & Techniques: Emphasis on MATLAB for solving circuit problems and analyzing transfer functions.
Introduction: Overview of the necessity for computer-aided circuit analysis due to the complexity of circuits and lack of closed-form solutions.
Fundamental Concepts: Key theories and laws governing electronic circuits, including Kirchhoff's and Ohm's laws.
Network Equations: Techniques like nodal and mesh analysis for deriving and solving circuit equations, using matrix representations.
Modeling of Devices: Representation of resistors, capacitors, and inductors through impedance and admittance models in the time and frequency domains.
Design and Optimization: Using simulations to evaluate circuit stability, sensitivity, and optimize performance.
Solution Methods: Numerical approaches for solving circuits, including Gaussian elimination, LU decomposition, and MATLAB simulations for real-time circuit behavior analysis.
Tools & Techniques: Emphasis on MATLAB for solving circuit problems and analyzing transfer functions.
- Teacher: أ. عيسي احمد