Integrates the most relevant aspects of signals and systems, circuit theory, mathematical techniques, and graphics into a coherent flow at reasonable depth
Covers a vast range of applications, ranging from RLC circuits, signal integrity, power delivery, feedback, transistor modeling, scattering parameters, multi-port networks, transmission lines, analog circuits, stability,sampling, algorithms, and numerical techniques
Follows a uniform presentation throughout, starting with theory at each stage, presenting multiple methods to solve the given problem, generating a solution and comparing to Spice results
Demonstrates scientific and visual computation both in the time and frequency domain, with special emphasis on computations in the complex plane, spectral analysis, inverse transforms and distributed media
Emphasizes root concepts and particular ins-and-outs of spectral and convolution techniques, which are gradually developed into simpler examples, culminating with real applications, then algorithmically coded, visualized and tested
Utilizes computer simulations, but with the barest lines of code to achieve satisfactory results
Driven by the authors´ industrial experience, but rooted in academic research with ample use of applications, examples, algorithms and verifications
Fuad Badrieh is a Senior Member of Technical Staff Engineer at Micron Technology, in Boise, Idaho. He obtained his BS, MS and PhD in EE at Arizona State University. He brings 17 years of industrial experience in modelling, circuit design, power integrity and automation.
This book describes a set of tools and algorithms then enable the electrical engineer in fields such as circuit design, power delivery, signal integrity, analog design, package and board modeling to arrive at approximate and exact solutions robustly and relatively efficiently, even when typical software packages may fail to do so. By leveraging well established and time tested methods, the author demonstrates how the practitioner will be able to deal with various circuit design problems and signal integrity issues both in the frequency and time domains. The presented tool set is an alternative to "brute force” time discretization and software utilization, offering great insight into the operations of linear systems ranging from RLC networks to device modeling.
|Integrates the most relevant aspects of signals and systems, circuit theory, mathematical techniques, and graphics into a coherent flow at reasonable depth
Covers a vast range of applications, ranging from RLC circuits, signal integrity, power delivery, feedback, transistor modeling, scattering parameters, multi-port networks, transmission lines, analog circuits, stability,sampling, algorithms, and numerical techniques
Follows a uniform presentation throughout, starting with theory at each stage, presenting multiple methods to solve the given problem, generating a solution and comparing to Spice results
Driven by the authors´ industrial experience, but rooted in academic research with ample of applications, examples, algorithms and verifications
1 Introduction
2 Steady State Solutions to Circuit Problems
3 Differential Equation Solution to Circuit Problems
4 Series Expansion solution for Circuit Problems
5 Numerical Differential Equation Solution to Circuit Problems
6 Fourier Series and Periodic Functions
7 Complex Fourier Series
8 Fourier Transform
9 Properties of the Fourier Transforms
10 Further Examples/Topics on Fourier Transform
11 Fourier Transform of Periodic Signals
12 Approximate and Numerical Techniques in Fourier Transform
13 Bandwidth
14 Laplace Transform
15 Using Complex Integration to Figure Inverse Laplace Transform
16 Properties of Laplace Transform
17 Laplace Transform of Periodic Functions
18 Finding Inverse Laplace Transform via Partial Fractions
19 Convolution
20 Signal Construction in Terms of Convolution Integrals
21 The Delta Function
22 Impulse Response
23 Time Convolution with Impulse Response
24 Time Convolution with the Unit Step Response
25 Sampling and the Sampling Theorem
26 Transfer Functions
27 The Phase
28 Stability and Relation to Poles Placements
29 Impulse Response as Configured from Inverse Transform
30 Unit Step Response as Configured from Inverse Transform
31 Pulse response
32 Causal Cosine and Sine Response
33 Causal, Periodic Pulse Response
34 Slanted Unit Step Response
35 Voltage/Voltage Filters
36 RLC Circuits with Feedback
37 Matrix Solution to MultiBranch Networks
38 MultiSource Networks and Superposition
39 Systems with Initial Conditions
40 Application to Transistor Modeling and Circuits
41 Op-Amp Filters
42 Multi-port Network: Z-, Y-Parameters
43 Scattering (s–) Parameters
44 Application of Spectral Techniques to Solving 2D Electrostatic Problems
45 Application of Spectral Techniques in Solving Diffusion Problems
46 Application of Spectral Techniques in Solving the Wave Equation
Appendix
References
Index
This book describes a set of tools and algorithms then enable the electrical engineer in fields such as circuit design, power delivery, signal integrity, analog design, package and board modeling to arrive at approximate and exact solutions robustly and relatively efficiently, even when typical software packages may fail to do so. By leveraging well established and time tested methods, the author demonstrates how the practitioner will be able to deal with various circuit design problems and signal integrity issues both in the frequency and time domains. The presented tool set is an alternative to "brute force” time discretization and software utilization, offering great insight into the operations of linear systems ranging from RLC networks to device modeling.
- Integrates the most relevant aspects of signals and systems, circuit theory, mathematical techniques, and graphics into a coherent flow at reasonable depth;
- Covers a vast range of applications, ranging from RLC circuits, signal integrity, power delivery, feedback, transistor modeling, scattering parameters, multi-port networks, transmission lines, analog circuits, stability,sampling, algorithms, and numerical techniques;
- Follows a uniform presentation throughout, starting with theory at each stage, presenting multiple methods to solve the given problem, generating a solution and comparing to Spice results;
- Demonstrates scientific and visual computation both in the time and frequency domain, with special emphasis on computations in the complex plane, spectral analysis, inverse transforms and distributed media;
- Emphasizes root concepts and particular ins-and-outs of spectral and convolution techniques, which are gradually developed into simpler examples, culminating with real applications, then algorithmically coded, visualized and tested;
- Utilizes computer simulations, but with the barest lines of code to achieve satisfactory results;
- Driven by the authors´ industrial experience, but rooted in academic research with ample use of applications, examples, algorithms and verifications.
This book describes a set of tools and algorithms then enable the electrical engineer in fields such as circuit design, power delivery, signal integrity, analog design, package and board modeling to arrive at approximate and exact solutions robustly and relatively efficiently, even when typical software packages may fail to do so. By leveraging well established and time tested methods, the author demonstrates how the practitioner will be able to deal with various circuit design problems and signal integrity issues both in the frequency and time domains. The presented tool set is an alternative to "brute force" time discretization and software utilization, offering great insight into the operations of linear systems ranging from RLC networks to device modeling.
1 Introduction 2 Steady State Solutions to Circuit Problems 3 Differential Equation Solution to Circuit Problems 4 Series Expansion solution for Circuit Problems 5 Numerical Differential Equation Solution to Circuit Problems 6 Fourier Series and Periodic Functions 7 Complex Fourier Series 8 Fourier Transform 9 Properties of the Fourier Transforms 10 Further Examples/Topics on Fourier Transform 11 Fourier Transform of Periodic Signals 12 Approximate and Numerical Techniques in Fourier Transform 13 Bandwidth 14 Laplace Transform 15 Using Complex Integration to Figure Inverse Laplace Transform 16 Properties of Laplace Transform 17 Laplace Transform of Periodic Functions 18 Finding Inverse Laplace Transform via Partial Fractions 19 Convolution 20 Signal Construction in Terms of Convolution Integrals 21 The Delta Function 22 Impulse Response 23 Time Convolution with Impulse Response 24 Time Convolution with the Unit Step Response 25 Sampling and the Sampling Theorem 26 Transfer Functions 27 The Phase 28 Stability and Relation to Poles Placements 29 Impulse Response as Configured from Inverse Transform 30 Unit Step Response as Configured from Inverse Transform 31 Pulse response 32 Causal Cosine and Sine Response 33 Causal, Periodic Pulse Response 34 Slanted Unit Step Response 35 Voltage/Voltage Filters 36 RLC Circuits with Feedback 37 Matrix Solution to MultiBranch Networks 38 MultiSource Networks and Superposition 39 Systems with Initial Conditions 40 Application to Transistor Modeling and Circuits 41 Op-Amp Filters 42 Multi-port Network: Z-, Y-Parameters 43 Scattering (s-) Parameters 44 Application of Spectral Techniques to Solving 2D Electrostatic Problems 45 Application of Spectral Techniques in Solving Diffusion Problems 46 Application of Spectral Techniques in Solving the Wave Equation Appendix References Index
Fuad Badrieh is a Senior Member of Technical Staff Engineer at Micron Technology, in Boise, Idaho. He obtained his BS, MS and PhD in EE at Arizona State University. He brings 17 years of industrial experience in modelling, circuit design, power integrity and automation.
Über den Autor
Fuad Badrieh is a Senior Member of Technical Staff Engineer at Micron Technology, in Boise, Idaho. He obtained his BS, MS and PhD in EE at Arizona State University. He brings 17 years of industrial experience in modelling, circuit design, power integrity and automation.
Inhaltsverzeichnis
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.
Klappentext
This book describes a set of tools and algorithms then enable the electrical engineer in fields such as circuit design, power delivery, signal integrity, analog design, package and board modeling to arrive at approximate and exact solutions robustly and relatively efficiently, even when typical software packages may fail to do so. By leveraging well established and time tested methods, the author demonstrates how the practitioner will be able to deal with various circuit design problems and signal integrity issues both in the frequency and time domains. The presented tool set is an alternative to "brute force" time discretization and software utilization, offering great insight into the operations of linear systems ranging from RLC networks to device modeling.
Integrates the most relevant aspects of signals and systems, circuit theory, mathematical techniques, and graphics into a coherent flow at reasonable depth
Covers a vast range of applications, ranging from RLC circuits, signal integrity, power delivery, feedback, transistor modeling, scattering parameters, multi-port networks, transmission lines, analog circuits, stability,sampling, algorithms, and numerical techniques
Follows a uniform presentation throughout, starting with theory at each stage, presenting multiple methods to solve the given problem, generating a solution and comparing to Spice results
Driven by the authors' industrial experience, but rooted in academic research with ample of applications, examples, algorithms and verifications
