PSpice for digital signal processing
PSpice for Digital Signal Processing is the last in a series of five books using Cadence Orcad PSpice version 10.5 and introduces a very novel approach to learning digital signal processing (DSP). DSP is traditionally taught using Matlab/Simulink software but has some inherent weaknesses for student...
| Main Author: | |
|---|---|
| Format: | Electronic |
| Language: | English |
| Published: |
San Rafael, Calif. (1537 Fourth Street, San Rafael, CA 94901 USA) :
Morgan & Claypool Publishers,
c2007.
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| Edition: | 1st ed. |
| Series: | Synthesis lectures on digital circuits and systems (Online) ;
#11. |
| Subjects: | |
| Online Access: | Abstract with links to full text |
Table of Contents:
- Introduction to digital signal processing
- Sampling
- Aliasing
- The ADC parameters
- Digital frequency
- Digital samples
- Delay unit and hierarchical blocks
- Transmission line delay
- Laplace delay
- DSP signals: Unit step signal
- Unit impulse signal
- Decaying exponential signal
- Digital sequences
- The z-transform
- Unit impulse
- Unit step
- Unit delay
- Exercises
- Difference equations and the z-transform
- Linear time-invariant systems
- Difference equations
- Digital filter classification
- First-order FIR filter
- z-transforms and difference equations
- Pole-zero constellation and Bibo stability
- Cut-off frequency
- Infinite impulse response filter
- First-order low-pass IIR filter
- Cut-off frequency for the IIR filter
- IIR phase response
- High-pass IIR filter
- The -3 dB cut-off frequency
- Passband gain
- Step response
- Impulse testing
- Bandpass IIR digital filter
- Bandpass pole-zero plot
- The -3 dB cut-off frequency
- Bandpass impulse response
- Simulating digital filters using a netlist
- Digital filters using a Laplace part
- Third-order elliptical filter
- Group delay
- Exercises
- Digital convolution, oscillators, and windowing
- Digital convolution
- Flip and slip method
- DSP sinusoidal oscillator
- Exercises
- Digital filter design methods
- Filter types
- Direct form 1 filter
- Direct form 2 filter
- The transpose filter
- Cascade and parallel filter realizations
- Digital filter specification
- The bilinear transform
- Designing digital filters using the bilinear transform method
- The impulse-invariant filter design technique
- Impulse function generation
- Sampling the impulse response
- Mapping from the s-plane to the z-plane
- Truncating IIR responses to show Gibbs effect
- Designing second-order filters using the impulse-invariant method
- Windowing
- Windows plots
- Windows spectral plots
- Window filter design
- Bartlett window
- The sampled impulse response
- Impulse response of a brick-wall filter
- Designing filters using the window method
- FIR root-raised cosine filter
- Raised cosine FIR filter design
- Root-raised cosine FIR filter design
- Exercises
- Digital signal processing applications
- Telecommunication applications
- Quadrature carrier signals
- Hilbert transform
- The Hilbert impulse response
- The Hilbert amplitude and phase responses
- Single-sideband suppressed carrier modulation
- Differentiator
- Integrator
- Multirate systems: Decimation and interpolation
- Decimation
- Example
- Solution
- Aliasing
- Interpolation
- Decimation and interpolation for noninteger sampling frequencies
- Exercises
- Down-sampling and digital receivers
- Receiver design
- RF sampling
- Down-sampling a passband signal
- Down-sampling a single-sideband signal
- Digital receiver
- DSP and music
- Phasing effect
- Zero-forcing equalizer
- Three-tap zero-forcing equalizer
- Example
- Solution
- Exercises.