Spectral, Convolution and Numerical Techniques in Circuit Theory

Introduction.- Steady State Solutions to Circuit Problems.- Differential Equation Solution to Circuit Problems.- Series Expansion solution for Circuit Problems.- Numerical Differential Equation Solution to Circuit Problems.- Fourier Series and Periodic Functions.- Complex Fourier Series.- Fourier Transform.- Properties of the Fourier Transforms.- Further Examples/Topics on Fourier Transform.- Fourier Transform of Periodic Signals.- Approximate and Numerical Techniques in Fourier Transform.- Bandwidth.- Laplace Transform.- Using Complex Integration to Figure Inverse Laplace Transform.- Properties of Laplace Transform.- Laplace Transform of Periodic Functions.- Finding Inverse Laplace Transform via Partial Fractions.- Convolution.- Signal Construction in Terms of Convolution Integrals.- The Delta Function.- Impulse Response.- Time Convolution with Impulse Response.- Time Convolution with the Unit Step Response.- Sampling and the Sampling Theorem.- Transfer Functions.- The Phase.- Stability and Relation to Poles Placements.- Impulse Response as Configured from Inverse Transform.- Unit Step Response as Configured from Inverse Transform.- Pulse response.- Causal Cosine and Sine Response.- Causal, Periodic Pulse Response.- Slanted Unit Step Response.- Voltage/Voltage Filters.- RLC Circuits with Feedback.- Matrix Solution to MultiBranch Networks.- MultiSource Networks and Superposition.- Systems with Initial Conditions.- Application to Transistor Modeling and Circuits.- Op-Amp Filters.- Multi-port Network: Z-, Y-Parameters.- Scattering (s-) Parameters.- Application of Spectral Techniques to Solving 2D Electrostatic Problems.- Application of Spectral Techniques in Solving Diffusion Problems.- Application of Spectral Techniques in Solving the Wave Equation.- Appendix.- References.- Index.