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数字信号处理和滤波器设计入门的经典教材,目录如下:
( f3 v& L" g/ ?7 |# vPreface xi
3 {! y8 Q4 A9 P9 e* }$ w1 Introduction 14 f, _0 H* X; s8 ^3 M3 `) w
1.1 Introduction 1* V+ C4 l! X$ f* A4 n+ L9 ^ ~
1.2 Applications of DSP 1
: r, E" g* w2 M1 c4 O1.3 Discrete-Time Signals 3
3 n( r8 ^& k, m' m1.3.1 Modeling and Properties of Discrete-Time Signals 8
) N- Q* x* ~7 x4 h1 W" T( F6 V1.3.2 Unit Pulse Function 9
$ @' d% W5 o" V+ P- v7 c1.3.3 Constant Sequence 10
2 Y2 w0 N: t* V: Y: N2 z2 J1.3.4 Unit Step Function 10
* l" ~+ v3 `: Y1.3.5 Real Exponential Function 12( l+ B4 @5 N5 ^% H4 v+ \
1.3.6 Complex Exponential Function 12
6 B q/ P/ `' K4 ~9 s" L1.3.7 Properties of cos(ω0n) 14( X) _8 o5 k( X8 m
1.4 History of Filter Design 19
2 L( W3 y$ K" x2 [1.5 Analog and Digital Signal Processing 234 o6 l5 u4 i+ h
1.5.1 Operation of a Mobile Phone Network 25! Y/ {- ^ {1 v* K; |
1.6 Summary 28
? G/ f% _3 F3 G/ q3 |9 B5 D7 lProblems 29! E' t8 V7 g0 |4 a& ~
References 304 F+ D0 }) E! o% `
2 Time-Domain Analysis and z Transform 324 j, ]$ E0 C5 S9 {
2.1 A Linear, Time-Invariant System 32% ]. W* D1 z& j; L4 H( K
2.1.1 Models of the Discrete-Time System 332 s8 x7 s8 {6 m' }, ]6 v5 H
2.1.2 Recursive Algorithm 36 d1 [8 B% ^% p# L
2.1.3 Convolution Sum 38$ a/ K4 o3 b6 x9 I" m
2.2 z Transform Theory 41
. e/ I3 I- @. J2 L/ U2.2.1 Definition 41! n0 T" b+ a, k9 p
2.2.2 Zero Input and Zero State Response 49
7 y$ B# M9 u6 R+ m, L9 H2.2.3 Linearity of the System 50& l* b4 C- _% g$ u/ {; m
2.2.4 Time-Invariant System 50
$ p- a* |. j- h" q4 C: d8 f2.3 Using z Transform to Solve Difference Equations 51
8 ~! z3 U9 ~9 J0 a2.3.1 More Applications of z Transform 567 b! Q* i9 p" ^
2.3.2 Natural Response and Forced Response 58# ^$ K7 z6 I% v
2.4 Solving Difference Equations Using the Classical Method 597 ^8 Q+ m" y0 k& S0 C
2.4.1 Transient Response and Steady-State Response 63
7 b' ?/ z- `- Q. ]. [5 e2.5 z Transform Method Revisited 64, @, @3 @! ]3 X5 z
2.6 Convolution Revisited 65
4 m r& @6 }4 b8 G2.7 A Model from Other Models 70
7 ~7 l4 V; I+ s. W- F7 d% d2.7.1 Review of Model Generation 72: }9 B! y' _. Y
2.8 Stability 770 r& x6 [) b) H; i7 p
2.8.1 Jury–Marden Test 78# Q" H5 a. o k$ r# w L
2.9 Solution Using MATLAB Functions 811 X: ?4 k- k, m0 w9 |- y1 b; k; Z
2.10 Summary 93% C! `! f& _& E, U1 q$ U2 B. i1 i
Problems 94
( x" P. b/ s: I& i4 i0 SReferences 110* x( o. P% H( ? A) \) Q
3 Frequency-Domain Analysis 1121 A7 w. K, N6 o/ Y# W9 e; I
3.1 Introduction 112. W& c4 h, C' v R1 C% \ }
3.2 Theory of Sampling 1135 i3 v5 F0 s+ Q9 N5 |. w
3.2.1 Sampling of Bandpass Signals 120, s* e5 `. m; {. c2 E# G
3.3 DTFT and IDTFT 122
; P& ^* Q% D, G4 e5 r' {3.3.1 Time-Domain Analysis of Noncausal Inputs 125
) _. X. ]( S, M( C& x$ j3.3.2 Time-Shifting Property 1277 T& k/ ^& M* d# O6 q$ D. u
3.3.3 Frequency-Shifting Property 127 d$ u& w( t% `! A
3.3.4 Time Reversal Property 1287 {. h' w4 f( X# p* E" `
3.4 DTFT of Unit Step Sequence 138
1 y. V3 C. T8 i( E( Q3.4.1 Differentiation Property 139
2 W% o& B8 i; z! C. B3.4.2 Multiplication Property 142
% \' O" @$ G' K& ^. {3.4.3 Conjugation Property 145 B$ W. \3 @+ o3 P+ p
3.4.4 Symmetry Property 145
. t, U+ l1 s9 ~/ C- D% T" i3.5 Use of MATLAB to Compute DTFT 147- c. o) O# x+ ~8 \! b
3.6 DTFS and DFT 154) x1 G1 C! g% D& D; |6 ~
3.6.1 Introduction 1549 ^3 _. w) a$ t" o3 T9 l
3.6.2 Discrete-Time Fourier Series 1567 L- u# @# p) a7 z% A) }6 X1 j
3.6.3 Discrete Fourier Transform 159 G% f0 K* H" I( r# t% z: F0 {# K
3.6.4 Reconstruction of DTFT from DFT 160
+ \4 j; M4 U$ L' U+ P3.6.5 Properties of DTFS and DFT 1614 b9 F8 l/ {) `2 K/ y" B0 ?* J
3.7 Fast Fourier Transform 170
( e" h0 K, F- c3.8 Use of MATLAB to Compute DFT and IDFT 172. h4 q, [/ f( I3 ~
3.9 Summary 177$ W8 s5 d- j' L
Problems 178; Q% {$ o- G/ H4 o5 m: E& p
References 185! F9 A7 R* ?4 v P. H1 z& D; ?2 o
4 Infinite Impulse Response Filters 186
% g) y* F) w& I9 W, f$ {4.1 Introduction 1863 y6 f7 F6 p+ N3 }* z
4.2 Magnitude Approximation of Analog Filters 189
6 {- u& t% V( `6 d. U5 N. ~4.2.1 Maximally Flat and Butterworth Approximation 191 c. V$ C3 j5 |: Z5 m
4.2.2 Design Theory of Butterworth Lowpass Filters 194
% f0 R# C4 Y8 e7 E8 k( O2 w4.2.3 Chebyshev I Approximation 202% L. a( {6 n x0 j* D7 q A E
4.2.4 Properties of Chebyshev Polynomials 2023 L5 \7 I- L1 N4 E1 m
4.2.5 Design Theory of Chebyshev I Lowpass Filters 204
: X. y( a+ E2 k. x4.2.6 Chebyshev II Approximation 208
$ X. ?$ u$ n/ m/ |3 V& l4.2.7 Design of Chebyshev II Lowpass Filters 210( `2 @1 c# X! Z @2 P1 z
4.2.8 Elliptic Function Approximation 212
7 q* Z S% u* H; @4 m6 z4.3 Analog Frequency Transformations 212& f. o! x2 b$ ?0 D# Z
4.3.1 Highpass Filter 212
$ b. H2 {: V8 ~. L/ n8 b; m! Y4.3.2 Bandpass Filter 213
2 x4 e: W7 V; w1 y. Y/ v, X4.3.3 Bandstop Filter 216$ H x/ D$ c/ _% z! m3 j7 O$ c
4.4 Digital Filters 2199 A. R8 @& o# T( E) e0 G4 d; x
4.5 Impulse-Invariant Transformation 219" T6 n& M5 `" T8 F5 q& `6 f1 R
4.6 Bilinear Transformation 221
( y+ i& k( ^, \! l4.7 Digital Spectral Transformation 2269 J, e. l+ e0 {& s4 {+ y
4.8 Allpass Filters 230
% }7 R3 P( h) v3 R& F( }4.9 IIR Filter Design Using MATLAB 2311 A$ H) ?, g* u
4.10 Yule–Walker Approximation 238
0 C" O6 ` Q* l" c! ^4.11 Summary 240
- I8 c+ g5 L4 M0 W& ^* yProblems 240
4 w- Y' q3 g2 i7 r/ `References 247
7 N6 G' p1 i, m4 d$ V+ Q E; D5 Finite Impulse Response Filters 249) \* T6 O5 u7 P( C" o+ s5 i/ P
5.1 Introduction 249
- B. u* p/ a1 N: H2 ?5.1.1 Notations 250
/ L, r% ]9 g6 |8 M# W) x# n5.2 Linear Phase Fir Filters 251( B$ m2 w+ k6 F+ y, m+ @% f, v7 G
5.2.1 Properties of Linear Phase FIR Filters 2564 Q7 Q1 f* `) |. @' G7 v$ }
5.3 Fourier Series Method Modified by Windows 261/ P2 b% a6 h0 ]9 N
5.3.1 Gibbs Phenomenon 263
; H3 W; ?( V( Y5.3.2 Use of Window Functions 266
; z5 q+ p1 T* `$ e6 e1 C# ]: e5.3.3 FIR Filter Design Procedures 268* Z/ g0 z" P5 }% t( g. t) P E/ |* x
5.4 Design of Windowed FIR Filters Using MATLAB 273
/ T3 l) \) n' L6 M5.4.1 Estimation of Filter Order 2731 C4 i/ t2 H$ @+ Q; s2 ~3 }
5.4.2 Design of the FIR Filter 275
1 f# t' U' N, V$ l$ l5.5 Equiripple Linear Phase FIR Filters 280
" u4 r5 P4 I* h% C5.6 Design of Equiripple FIR Filters Using MATLAB 285
' }: v# U* Q9 W3 J+ j7 N2 q7 f5.6.1 Use of MATLAB Program to Design Equiripple FIR Filters 2855 H, X6 }( F; G
5.7 Frequency Sampling Method 289& Y! F1 D1 J9 D& j& g$ @
5.8 Summary 292
) o. t+ p( N2 m& i' D" V" SProblems 294/ r6 U7 z+ O/ D# [3 w" A& l, @
References 301
% ~6 m; ]2 {$ k& L/ a3 F6 Filter Realizations 3037 _* w2 B: o, @, r
6.1 Introduction 303& n% W) O$ n7 `9 d2 ?0 C7 |
6.2 FIR Filter Realizations 3053 I u4 H$ F: {; {, z( c! X
6.2.1 Lattice Structure for FIR Filters 309
2 ^9 \+ T0 w7 W6.2.2 Linear Phase FIR Filter Realizations 310" P& \- a2 h0 Y$ m1 e; R
6.3 IIR Filter Realizations 312
% ?5 E0 R0 y: R4 w' s' r6 ~6.4 Allpass Filters in Parallel 320
( W: V ]& C1 q, w6.4.1 Design Procedure 325
8 x& [) c' C* Y; K( Q8 E6.4.2 Lattice–Ladder Realization 326
) i7 t) U6 E. Q W# {* R1 m3 \6.5 Realization of FIR and IIR Filters Using MATLAB 3275 J6 e: O8 O" E% T" F
6.5.1 MATLAB Program Used to Find Allpass Filters in Parallel 334
& d8 A' \) F+ q: k& }- i6.6 Summary 346
+ ]9 @$ x5 d4 z5 E9 K# ~Problems 347
$ _8 l9 z% s- ~References 3539 ~- H2 k' V9 A% L
7 Quantized Filter Analysis 354) b# `* s/ Q8 q3 e+ J% R$ \* k: r
7.1 Introduction 354* W4 o2 u1 ` V$ ?; y- n8 Y
7.2 Filter Design–Analysis Tool 355
7 Z1 X& d' o& _4 q% d0 t6 F$ D) u7.3 Quantized Filter Analysis 360
6 T F3 u2 s6 |6 ^2 [3 M7.4 Binary Numbers and Arithmetic 360
. t( z6 ^ p1 {- Y: q, W8 t' Y7.5 Quantization Analysis of IIR Filters 3676 {/ s t) }8 ~2 @1 j4 k Q- @
7.6 Quantization Analysis of FIR Filters 375
( Y' K1 j& Y) Z! L7.7 Summary 379$ J( @" }/ o; }; v0 e
Problems 379
2 Y& N: d6 q) g4 ^. J; m) y3 H1 YReferences 379# c2 G/ V: ?$ X- Y1 U# u% z
8 Hardware Design Using DSP Chips 3819 B3 h# [4 a) H, o
8.1 Introduction 381
* k3 K/ q0 }/ U9 _8.2 Simulink and Real-Time Workshop 3819 w3 C% \$ {+ W! \
8.3 Design Preliminaries 383
- h# U, v* I6 n: k0 I8 n/ e3 j) a8.4 Code Generation 385
5 g. ~ e* O, ]4 c8 r; v* x2 U8.5 Code Composer Studio 386
( H+ o- R. |6 R# T- X8.6 Simulator and Emulator 388
, X. T. j# B& J$ N: E8 O8.6.1 Embedded Target with Real-Time Workshop 389
^+ v+ o8 v% u+ V8.7 Conclusion 3897 O! t( O+ W. ^) U% P% R4 M3 a
References 390: L# ^4 M+ }6 }* x' |
9 MATLAB Primer 391
% J5 O) L: x/ v/ R- l3 s9.1 Introduction 391& a: Z& i; C4 o' k7 k2 n5 T
9.1.1 Vectors, Arrays, and Matrices 3928 v' Q& k7 p2 o3 v
9.1.2 Matrix Operations 393; k; \6 b. M# N
9.1.3 Scalar Operations 3986 M7 i% D6 b1 H7 q1 x$ Y1 w4 n7 l
9.1.4 Drawing Plots 400
) y( s; u/ y3 }8 E0 g9.1.5 MATLAB Functions 400
. h4 l7 @! U$ k" [8 y' }0 ^9.1.6 Numerical Format 401) }: N) _3 Z. M7 o
9.1.7 Control Flow 402
4 f6 n5 [- y- c5 J3 z9.1.8 Edit Window and M-file 403. O/ R; h2 \) P1 V; y) @
9.2 Signal Processing Toolbox 405+ l I& }2 J% Y
9.2.1 List of Functions in Signal Processing Toolbox 406
8 c u; J6 B! UReferences 414
. |8 }# H. V/ o9 `0 @: J. C4 _8 BIndex 415' E1 \$ |8 G+ l
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发表于 2016-11-23 11:14
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