| Description |
1 online resource (xiii, 151 pages) |
| Series |
Synthesis lectures on digital circuits and systems ; #8 |
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Synthesis lectures on digital circuits and systems (Online) ; #8.
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| Contents |
Passive filters and Bode plotting -- Filter types -- Decibels -- The cut-off frequency -- Filter specification -- Transfer function: First-order low-pass CR filter -- Bode plotting -- Low-pass CR filter phase response -- Markers -- Cut-off frequency and roll-off rate -- Asymptotic filter response plotting using an Ftable part -- High-pass CR filter -- Phase response measurement -- Group delay -- Modified low-pass filter -- Modified high-pass filter -- Voltage-controlled low-pass and high-pass filters -- Nichols chart and a lag network -- Exercises -- Loss functions and active filter design -- Approximation loss functions -- Butterworth approximating function -- The frequency scaling factor and filter order -- Butterworth tables -- Chebychev approximating functions -- Chebychev tables -- Ripple factor and Chebychev order -- Plotting Chebychev and Butterworth function -- Amplitude response for a first-order active low-pass filter -- Exercises -- Voltage-controlled voltage source active filters -- Filter types -- Voltage-controlled voltage source filters (VCVS) -- Sallen and key low-pass active filter -- Example -- Sallen and key low-pass filter impulse response -- Filter amplitude response -- Solution -- Butterworth third order active high-pass filter -- The second-order transfer function -- Exercises -- Infinite gain multiple feedback active filters -- Multiple feedback active filters -- Simulation from a netlist -- Chebychev IGMF bandpass filter -- Expressions for Q and BW -- Chebychev bandpass active filter -- Example -- Low-pass frequency response -- Exercises -- Biquadratic filters and Monte-Carlo analysis -- Biquad active filter -- The Biquad bandpass transfer function -- Equal value component -- State-variable filter -- Bandpass frequency response -- Monte Carlo analysis and histograms -- Sixth-order LPF active filter -- Component tolerance -- Performance histograms -- Exercises -- Switched-capacitor filter circuits -- Electronic integration -- Active integration -- Active leaky integrator -- Switched-capacitor circuits -- Switched-capacitor low-pass filter step response -- Switched capacitor integrator -- Electronic differentiation -- Exercises -- Two-port networks and transmission lines -- Two-port networks -- The z-parameters -- Z-equivalent circuit -- Current gain -- The output impedance -- Input impedance -- The voltage gain -- Symmetrical and unbalanced networks -- Asymmetrical networks and image impedances -- Two-port resistive T-attenuators -- Transmission line model -- Forward and backward Waves -- Characteristic impedance -- Transmission line types -- Lossless transmission line parameters -- Lossy transmission line parameters -- Voltage standing wave ratio (VSWR) -- Input impedence of a transmission line -- Solution -- Quarter-wave transmission line matching -- Solution -- Single-stub matching -- Problem 1 -- Solution -- Time domain reflectrometry -- The lattice/bounce diagram -- TDR for fault location on transmission lines -- Standing waves on a transmission line -- Exercises -- Importing and exporting speech signals -- Logic gates -- Busses and multiplex circuits -- Random access memory -- Digital comparator -- Seven-segment display -- Signal sources -- Function generator -- Importing speech -- Wav2Ascii -- Import a speech file into a schematic -- Reverberation/echo -- Recording a WAV file -- Matlab code -- Exporting speech -- Exercises -- Appendix A: References |
| Summary |
In this book, PSpice for Filters and Transmission Lines, we examine a range of active and passive filters where each design is simulated using the latest Cadence Orcad V10.5 PSpice capture software. These filters cannot match the very high order digital signal processing (DSP) filters considered in PSpice for Digital Signal Processing, but nevertheless these filters have many uses. The active filters considered were designed using Butterworth and Chebychev approximation loss functions rather than using the 'cookbook approach' so that the final design will meet a given specification in an exacting manner. Switched-capacitor filter circuits are examined and here we see how useful PSpice/Probe is in demonstrating how these filters, filter, as it were. Two-port networks are discussed as an introduction to transmission lines and, using a series of problems, we demonstrate quarter-wave and single-stub matching. The concept of time domain reflectrometry as a fault location tool on transmission lines is then examined. In the last chapter we discuss the technique of importing and exporting speech signals into a PSpice schematic using a tailored-made program Wav2ascii. This is a novel technique that greatly extends the simulation boundaries of PSpice. Various digital circuits are also examined at the end of this chapter to demonstrate the use of the bus structure and other |
| Notes |
Title from PDF title page (viewed March 28, 2007) |
| Bibliography |
Includes bibliographical references (pages 145-146) and index |
| SUBJECT |
PSpice. http://id.loc.gov/authorities/names/n91119141
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PSpice fast |
| Subject |
Electric filters -- Mathematical models
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Electric filters -- Computer simulation
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Electric lines -- Mathematical models
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Electric lines -- Computer simulation
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Electric power transmission -- Mathematical models
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Electric power transmission -- Computer simulation
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TECHNOLOGY & ENGINEERING -- Electronics -- Circuits -- General.
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TECHNOLOGY & ENGINEERING -- Electronics -- Circuits -- Integrated.
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Electric filters -- Mathematical models
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Electric lines -- Computer simulation
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Electric lines -- Mathematical models
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Electric power transmission -- Mathematical models
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| Form |
Electronic book
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| ISBN |
1598291599 |
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9781598291599 |
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9783031797644 |
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3031797647 |
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