Table of Contents:
“...Principles of FIR design -- Overview -- In previous volumes -- In this volume -- In this chapter -- Software for use with this book -- Characteristics of FIR filters -- Effect of filter length -- Effect of windowing -- Linear phase -- Impulse response requirement -- Four basic categories of FIR impulse response for linear phase -- Zero location in linear phase filters -- Linear phase FIR frequency content and response -- Design methods -- Basic scheme -- Three design methods -- The comb and moving average filters -- FIR realization -- Direct form -- Cascade form -- Linear phase form -- Cascaded linear phase form -- Frequency sampling -- References -- Exercises -- FIR design techniques -- Overview -- Software for use with this book -- Summary of design methods -- Filter specification -- FIR design via windowed ideal lowpass filter -- Windows -- Net frequency response -- Windowed lowpass filters-passband ripple and stopband -- Attenuation -- Highpass, bandpass, and bandstop filters from lowpass filters -- Improving stopband attenuation -- Meeting design specifications -- FIR design via frequency sampling -- Using the inverse DFT -- Using cosine/sine summation formulas -- Improving stopband attenuation -- Filters other than lowpass -- Hilbert transformers -- Differentiators -- Optimized filter design -- Equiripple design -- Design goal -- Alternation theorem -- A common design problem for all linear phase filters -- Weighted error function -- Remez exchange algorithm -- References -- Exercises -- Classical IIR design -- Overview -- Laplace transform -- Definition -- Convergence -- Relation to Fourier transform -- Relation to z-transform -- Time domain response generated by poles -- General observations -- Prototype analog filters -- Notation -- System function and properties --
Computed frequency response -- General procedure for analog/digital filter design -- Analog lowpass Butterworth filters -- Design by order and cutoff frequency -- Design by standard parameters -- Lowpass analog Chebyshev type-I filters -- Design by order, cutoff frequency, and Epsilon -- Design by standard parameters -- Lowpass analog Chebyshev type-II filters -- Design by order, cutoff frequency, and Epsilon -- Design by standard parameters -- Analog lowpass elliptic filters -- Design by standard parameters -- Frequency transformations in the analog domain -- Lowpass to lowpass -- Lowpass to highpass -- Transformation via convolution -- Lowpass to bandpass -- Lowpass to bandstop (notch) -- Analog to digital filter transformation -- Impulse invariance -- The bilinear transform -- MathScript filter design functions -- Prony's method -- IIR optimization
programs -- References -- Exercises -- Software for use with this book -- File types and
naming conventions -- Downloading the software -- Using the software -- Single-line function calls -- Multi-line m-code examples -- How to successfully copy-and-paste M-code -- Learning To use M-code -- What you need with MATLAB and LabVIEW -- Vector/matrix operations in M-code -- Row and column vectors -- Vector products -- Inner product -- Outer product -- Product of corresponding values -- Matrix multiplied by a vector or matrix -- Matrix inverse and pseudo-inverse -- FIR frequency sampling design formulas -- Whole-cycle mode filter formulas -- Odd length, symmetric (type I) -- Even length, symmetric (type II) -- Odd length, anti-symmetric (type III) -- Even length, symmetric (type IV) -- Half-cycle mode filters -- Odd length, symmetric (type I) -- Even length, symmetric (type II) -- Odd length, anti-symmetric (type III) -- Even length, anti-symmetric (type IV)....
”
Call Number:
Loading...
Located:
Loading...
Connect to the full text of this electronic book
Software download
eBook