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信号与系统:第2版
作者:Alan V. Oppenheim,Alan S. Willsky with S.Hamid Nawab著
出版社:清华大学出版社
出版时间:1999-01-01
ISBN:9787302030584
定价:¥44.00
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内容简介
本书是MIT电气式工程与计算机本科生教材。主编Oppenheim教授是本领域中的一个权威,在国际上享有盛名。相对于第1版,本书在内容编排上又进行了大幅度精心调整,各章节在内容编排上又进行了大幅度精心调整,各章之间的关系更合理,且充实了更丰富的内容,加强了实际应用方面的知识。全书共11章,分别为:信号与系统、线性时不变系统;周期信号的傅里叶级数表示;连续时间傅里叶变换;离散时间傅里叶变换;信号与系统的时域和频域特性;抽样;通信系统;拉普拉斯变换;Z变换;线性反馈系统。每章配有不同层次的习题,书后附有答案。“信号与系统”不仅是弱电类本科生必修的基本课程,而且,作为该课程核心的一些基本概念和方法,对所有式科专业来说也是非常重要的。
作者简介
暂缺《信号与系统:第2版》作者简介
目录
PREFACE XVII
ACKNOWLEDGMENTS XXV
FOREWORD XXVII
1 SIGNALS AND SYSTEMS l
l.0 Introduction 1
1.1 Continuous-Time and Discrete-Time Signals l
l.l.l Examples and Mathematical Representation l
I.l.2 Signal Energy and Power 5
l.2 Transformations of the Independent Variable 7
l.2.l Examp1es of Transformations of the Independent Variable 8
l.2.2 Periodic Signals ll
I.2.3 Even and Odd Signals l3
1.3 Exponential and Sinusoidal Signals 14
l.3.l Continuous-Time Complex Exponential and Sinusoidal Signals l5
l.3.2 Discrete-Time Complex Exponential and Sinusoidal Signals 2l
l.3.3 Periodicity Properties of Discrete-Time Complex Exponentials 25
1.4 The Unit Impulse and Unit Step Functions 30
l.4.1 The Discrete-Time Unit Impulse and Unit Step Sequences 30
l.4.2 The Continuous-Time Unit Step and Unit lmpul8e Functions 32
l.5 Continuous-Time and Discrete-Time Systems 38
l.5.l Simple Examples of Systems 39
1.5.2 Interconnections of Systems 4I
1.6 Basic System Properties 44
1.6.l Systems with and without Memory 44
l.6.2 Invertibility and Inverse Systems 45
l.6.3 Causality 46
l.6.4 Stability 48
1.6.5 Time Invariance 50
l.6.6 Linearity 53
1.7 Summary 56
Problems 57
2 LINEAR TIME-INVARIANT SYSTEMS 74
2.0 Introduction 74
2.1 Discrete-Time LTI Systems: The Convolution Sum 75
2.l.l The Representation of Discrete-Time Signals in Terms of Impulses 75
2.l.2 The Discrete-Time Unit Impulse Response and the Convolution-Sum Representation of LTI Systems 77
2.2 Continuous-Time LTI Systems: The Convolution Integral 90
2.2.l The Representation of Continuous-Time Signals in Terms of Impulses 90
2.2.2 The Continuous-Time Unit Impulse Response and the Convolution Integral Representation of LTI Systems 94
2.3 Properties of Linear Time-Invariant Systems 103
2.3.l The Commutative Property l04
2.3.2 The Distributive Property l04
2.3.3 The Associative Property l07
2.3.4 LTI Systems with and without Memory l08
2.3.5 Invertibility of LTI Systems l09
2.3.6 Causality for LTI Systems ll2
2.3.7 Stability for LTI Systems ll3
2.3.8 The Unit Step Response of an LTI System ll5
2.4 Causal LTI Systems Described by Differential and Difference Equations ll6
2.4.l Linear Constant-Coefficient Differential Equations ll7
2.4.2 Linear Constant-Coefficient Difference Equations l2l
2.4.3 Block Diagram Representations of First-Order Systems Described by Differential and Difference Equations l24
2.5 Singularity Functions l27
2.5.l The Unit Impulse as an Idealized Short Pulse l28
2.5.2 Defining the Unit Impulse through Convolution l3l
2.5.3 Unit Doublets and Other Singularity Functions l32
2.6 Summary 137
Problems l37
3 FOUBIER SERIES REPRESENTATON OF PERIODIC SIGNALS 177
3.0 Introduction l77
3.l A Historical Perspective l78
3.2 The Response of LTI Systems to Complex Exponentials 182
3.3 Fourier Series Representation of Continuous-Time Periodic Signals l86
3.3.l Linear Combinations of Harmonically Related Complex Exponentials l86
3.3.2 Determination of the Fourier Series Representation of a Continuous-Time Periodic Signal l90
3.4 Convergence of the Fourier Series l95
3.5 Properties of Continuous-Time Fourier Series 202
3.5.1 Linearity 202
3.5.2 Time Shifting 202
3.5.3 Time Reversal 203
3.5.4 Time Scaling 204
3.5.5 Multiplication 204
3.5.6 Conjugation and Conjugate Symmetry 204
3.5.7 Parseval's Relation for Continuous-Time Periodic Signals 205
3.5.8 Summary of Properties of the Continuous-Time Fourier Series 205
3.5.9 Examples 205
3.6 Fourier Series Representation of Discrete-Time Periodic Signals 211
3.6.l Linear Combinations of Harmonica11y Related Complex Exponentials 21l
3.6.2 Determination of the Fourier Series Representation of a Periodic Signal 2l2
3.7 Properties of Discrete-Time Fourier Series 221
3.7.l Multiplication 222
3.7.2 First Difference 222
3.7.3 Parseval's Relation for Discrete-Time Periodic Signals 223
3.7.4 Examp1es 223
3.8 Fourier Series and LTI Systems 226
3.9 Filtering 23l
3.9.l Frequency--Shaping Filters 232
3.9.2 Frequency Selective Filters 236
3.10 Examples of Continuous-Time Filt6rs Described by Differential Equations 239
3.l0.l A Simple RC Lowpass Filter 239
3.10.2 A Simple RC Highpass Fi1ter 241
3.11 Examples of Discrete-Time Filters Described by Difference Equations 244
3.11.l First-Order Recursive Discrete-Time Filters 244
3.l1.2 Nonrecursive Discrete-Time Filters 245
3.12 Summary 249
Problems 250
4 THE CONTINUOUS-TIME FOURIER TRANSFORM 284
4.0 Introduction 284
4.1 Representation of Aperiodic Signals: The Continuous-Time Fourier Transform 285
4.1.l Development of the Fourier Transform Representation of an Aperiodic Signal 285
4.1.2 Convergence of Fourier Transforms 289
4.1.3 Examples of Continuous-Time Fourier Transforms 290
4.2 The Fourier Transform for Periodic Signals 296
4.3 Properties of the Continuous-Time Fourier Transform 300
4.3.l Linearity 30l
4.3.2 Time Shifting 30l
4.3.3 Conjugation and Conjugate Symmetry 303
4.3.4 Differentiation and Integration 306
4.3.5 Time and Frequency Scaling 308
4.3.6 Duality 309
4.3.7 Parseval's Relation 3l2
4.4 The Convolution Property 3l4
4.4.l Examples 3l7
4.5 The Multiplication Property 322
4.5.l Frequency-Selective Filtering with Variab1e Center Frequency 325
4.6 Tables of Fourier Properties and Of Basic Fourier Transform Pairs 328
4.7 Systems Characterized by Linear Constant-Coefficient Differential Equations 330
4.8 Summary 333
Problems 334
5 THE DISCRETE-TIME FOURIER TRANSFORM 358
5.0 Introduction 358
5.l Representation of Aperiodic Signals: The Discrete-Time Fourier Transform 359
5.1.l Development of the Discrete-Time Fourier Transform 359
5.1.2 Examples of Discrete-Time Fourier Transforms 362
5.l.3 Convergence Issues Associated with the Discrete-Time Fourier Transform 366
5.2 The Fourier Transform for Periodic Signals 367
5.3 Properties of the Discrete-Time Fourier Transform 372
5.3.l Periodicity of the Discrete-Time Fourier Transform 373
5.3.2 Linearity of the Fourier Transform 373
5.3.3 Time Shifting and Frequency Shifting 373
5.3.4 Conjugation and Conjugate Symmetry 375
5.3.5 Differencing and Accumulation 375
5.3.6 Time Reversal 376
5.3.7 Time Expansion 377
5.3.8 Differentiation in Frequency 380
5.3.9 Parseval's Relation 380
5.4 The Convolution Property 382
5.4.l Examples 383
5.5 The Multiplication Property 388
5.6 Tables of Fourier Transform Properties and Basic Fourier Transform Pairs 390
5.7 Duality 390
5.7.1 Duality in the Discrete-Time Fourier Series 39l
5.7.2 Dua1ity between the Discrete-Time Fourier Transform and the Continuous-Time Fourier Series 395
5.8 Systems Characterized by Linear Constant-Coefficient Difference Equations 396
5.9 Summary 399
Problems 400
6 TIME AND FREQUENCY CHARACTERIZATION OF SIGNALS AND SYSTEMS 423
6.0 Introduction 423
6.1 The Magnitude-Phase Representation of the Fourier Transform 423
6.2 The Magnitude-Phase Representation of the Frequency Response of LTI Systems 427
6.2.l Linear and Non1inear Phase 428
6.2.2 Group De1ay 430
6.2.3 Log-Magnitude and Bode Plots 436
6.3 Time-Domain Properties of Ideal Frequency-Selective Filters as9
6.4 Time-Domain and Frequency-Domain Aspects of Nonideal Filters
6.5 First-Order and Second-Order Continuous-Time Systems 448
6.5.l First-Order Continuous-Time Systems 448
6.5.2 Second-Order Continuous--Time Systems 45l
6.5.3 Bode Plots for Rational Frequency Responses 456
6.6 First-Order and Second-Order Discrete-Time Systems 461
6.6.l First-Order Discrete-Time Systems 46l
6.6.2 Second-Order Discrete-Time Systems 465
6.7 Examples of Time-and Frequency-Domain Analysis Of Systems 472
6.7.1 Analysis of an Automobile Suspension System 473
6.7.2 Examples of Discrete-Time Nonrecursive Filters 476
6.8 Summary 482
Problems 483
7 SAMPLING 514
7.0 Introduction 5l4
7.1 Representation of a Continuous-Time Signal by Its Samples: The Sampling Theorem 515
7.1.l Impulse-Train Sampling 5l6
7.l.2 Sampling with a Zero-Order Hold 520
7.2 Reconstruction of a Signal from Its Samples Using Interpolation 522
7.3 The Effect Of Undersampling: Aliasing 527
7.4 Discrete-Time Processing of Continuous-Time Signals 534
7.4.1 Digital Differentiator 54l
7.4.2 Half Sample Delay 543
7.5 Sampling of Discrete-Time Signals 545
7.5.l Impulse-Train Sampling 545
7.5.2 Discrete-Time Decimation and Interpolation 549
7.6 Summary 555
Problems 556
8 COMMUNICATION SYSTEMS 582
8.0 Introduction 582
8.l Complex Exponential and Sinusoidal Amplitude Modulation 583
8.l.1 Amplitude Modulation with a Complex Exponential Carrier 583
8.l.2 Amplitude Modulation with a Sinusoidal Carrier 585
8.2 Demodulation for Sinusoidal AM 587
8.2.l Synchronous Demodulation 587
8.2.2 Asynchronous Demodulation 590
8.3 Frequency-Division Multiplexing 594
8.4 Single-Sideband Sinusoidal Amplitude Modulation 597
8.5 Amplitude Modulation with a Pulse-Train Carrier 601
8.5.l Modulation of a Pulse-Train Carrier 60l
8.5.2 Time-Division Multiplexing 604
8.6 Pulse-Amplitude Modulation 604
8.6.l Pulse-Amplitude Modulated Signals 604
8.6.2 Intersymbol Interference in PAM Systems 607
8.6.3 Digital Pulse-Amplitude and Pulse-Code Modulation 610
8.7 Sinusoidal Frequency Modulation 61l
8.7.l Narrowband Frequency Modulation 6l3
8.7.2 Wideband Frequency Modulation 6l5
8.7.3 Periodic Square-Wave Modulating Signal 617
8.8 Discrete-Time Modulation 6l9
8.8.l Discrete-Time Sinusoidal Amplitude Modulation 619
8.8.2 Discrete-Time Transmodulation 623
8.9 Summary 623
Problems 625
9 THE LAPLACE TRANSFORM 654
9.0 Introduction 654
9.l The Laplace Transform 655
9.2 The Region of Convergence for Laplace Transforms 662
9.3 The Inverse Laplace Transform 670
9.4 Geometric Evaluation of the Fourier Transform from the Pole-Zero Plot 674
9.4.l First-Order Systems 676
9.4.2 Second--Order Systems 677
9.4.3 All-Pass Systems 68l
9.5 Properties Of the Laplace Transform 682
9.5.l Linearity of the Laplace Transform 683
9.5.2 Time Shifting 684
9.5.3 Shifting in the s-Domain 685
9.5.4 Time Sca1ing 685
9.5.5 Conjugation 687
9.5.6 Convolution Property 687
9.5.7 Differentiation in the Time Domain 688
9.5.8 Differentiation in the s-Domain 688
9.5.9 Integration in the Time Domain 690
9.5.l0 The Initial- and Final-Value Theorems 690
9.5.l1 Table of Properties 691
9.6 Some Laplace Transform Pairs 692
9.7 Analysis and Characterization Of LTI Systems Using the Laplace Transform 693
9.7.1 Causality 693
9.7.2 Stability 695
9.7.3 LTI Systems Characterization by Linear Constant-Coefficient Differential Equations 698
9.7.4 Examples Relating System Behavior to the System Function 70l
9.7.5 Butterworth Filters 703
9.8 System Function Algebra and Block Diagram Representations 706
9.8.l System Functions for Interconnections of LTI Systems 707
9.8.2 Block Diagram Representations for Causal LTI Systems Described by Differential Equations and Rational System Functions 708
9.9 The Unilateral Laplate Transform 714
9.9.1 Examples of Unilateral Laplace Transforms 714
9.9.2 Properties of the Unilateral Laplace Transform 7l6
9.9.3 Solving Differential Equations Using the Unilateral Laplace Transform 719
9.10 Summary 720
Problems 72l
10 THE Z--TRANSFORM 741
l0.0 Introduction 741
10.1 The-Transform 741
l0.2 The Region Of Convergence for the z-Transform 748
l0.3 The Inverse z-Transform 757
l0.4 Geometric Evaluation of the Fourier Transform from the Pole-Zero Plot 763
l0.4.l First-Order Systems 763
l0.4.2 Second-Order Systems 765
l0.5 Properties of the z-Transform 767
l0.5.l Linearity 767
10.5.2 Time Shifting 767
10.5.3 Scaling in the z-Domain 768
l0.5.4 Time Reversal 769
l0.5.5 Time Expansion 769
l0.5.6 Conjugation 770
l0.5.7 The Convolution Property 770
l0.5.8 Differentiation in the z-Domain 772
l0.5.9 The Initial--Value Theorem 773
l0.5.l0 Summary of Properties 774
l0.6 Some Common z-Transform Pairs 774
l0.7 Analysis and Charact6rization Of LTI Systems Using z-Transforms 774
10.7.l Causality 776
l0.7.2 Stability 777
10.7.3 LTI Systems Characterized by Linear Constant-Coefficient Difference Equations 779
l0.7.4 Examples Relating System Behavior to the System Function 78
l0.8 System Function Algebra and Block Diagram
Representations 783
l0.8.1 System Functions for Interconnections of LTI Systems 784
l0.8.2 Block Diagram Representations for Causal LTI Systems Described by Difference Equations and Rational System Functions 784
l0.9 The Unilateral z-Transform 789
l0.9.l Examp1es of Unilatera1 z-Transforms and Inverse Transforms 790
l0.9.2 Properties of the Unilatera1 z-Transform 792
l0.9.3 Solving Difference Equations Using the Unilateral z-Transform 795
l0.l0 Summary 796
Problems 797
11 LINEAR FEEDBACK SYSTEMS 816
ll.0 Introduction 816
ll.1 Linear Feedback Systems 819
l1.2 Some Applications and Consequences of Feedback 820
ll.2.l Inverse System Design 820
ll.2.2 Compensation for Nonideal E1ements 82l
ll.2.3 Stabilization of Unstable Systems 823
ll.2.4 Sampled-Data Feedback Systems 826
ll.2.5 Tracking Systems 828
11.2.6 Destabilization Caused by Feedback 830
ll.3 Root-Locus Analysis Of Linear Feedback Systems 832
l1.3.l An Introductory Example 833
ll.3.2 Equation for the Closed-Loop Poles 834
ll.3.3 The End Points of the Root Locus: The Closed-Loop Poles for K=0 and |K| = + 836
ll.3.4 The Angle Criterion 836
11.3.5 Properties of the Root Locus 841
1l.4 The Nyquist Stability Criterion 846
ll.4.l The Encirclement Property 847
l1.4.2 The Nyquist Criterion for Continuous-Time LTI Feedback Systems 850
1l.4.3 The Nyquist: Criterion for Discrete--Time LTI Feedback Systems 856
11.5 Gain and Phase Margins 858
11.6 Summary 866
Problems 867
APPENDIX PARTIAL-FRACTION EXPANSION 909
BIBLIOGRAPHY 921
ANSWERS 93l
INDEX 941
ACKNOWLEDGMENTS XXV
FOREWORD XXVII
1 SIGNALS AND SYSTEMS l
l.0 Introduction 1
1.1 Continuous-Time and Discrete-Time Signals l
l.l.l Examples and Mathematical Representation l
I.l.2 Signal Energy and Power 5
l.2 Transformations of the Independent Variable 7
l.2.l Examp1es of Transformations of the Independent Variable 8
l.2.2 Periodic Signals ll
I.2.3 Even and Odd Signals l3
1.3 Exponential and Sinusoidal Signals 14
l.3.l Continuous-Time Complex Exponential and Sinusoidal Signals l5
l.3.2 Discrete-Time Complex Exponential and Sinusoidal Signals 2l
l.3.3 Periodicity Properties of Discrete-Time Complex Exponentials 25
1.4 The Unit Impulse and Unit Step Functions 30
l.4.1 The Discrete-Time Unit Impulse and Unit Step Sequences 30
l.4.2 The Continuous-Time Unit Step and Unit lmpul8e Functions 32
l.5 Continuous-Time and Discrete-Time Systems 38
l.5.l Simple Examples of Systems 39
1.5.2 Interconnections of Systems 4I
1.6 Basic System Properties 44
1.6.l Systems with and without Memory 44
l.6.2 Invertibility and Inverse Systems 45
l.6.3 Causality 46
l.6.4 Stability 48
1.6.5 Time Invariance 50
l.6.6 Linearity 53
1.7 Summary 56
Problems 57
2 LINEAR TIME-INVARIANT SYSTEMS 74
2.0 Introduction 74
2.1 Discrete-Time LTI Systems: The Convolution Sum 75
2.l.l The Representation of Discrete-Time Signals in Terms of Impulses 75
2.l.2 The Discrete-Time Unit Impulse Response and the Convolution-Sum Representation of LTI Systems 77
2.2 Continuous-Time LTI Systems: The Convolution Integral 90
2.2.l The Representation of Continuous-Time Signals in Terms of Impulses 90
2.2.2 The Continuous-Time Unit Impulse Response and the Convolution Integral Representation of LTI Systems 94
2.3 Properties of Linear Time-Invariant Systems 103
2.3.l The Commutative Property l04
2.3.2 The Distributive Property l04
2.3.3 The Associative Property l07
2.3.4 LTI Systems with and without Memory l08
2.3.5 Invertibility of LTI Systems l09
2.3.6 Causality for LTI Systems ll2
2.3.7 Stability for LTI Systems ll3
2.3.8 The Unit Step Response of an LTI System ll5
2.4 Causal LTI Systems Described by Differential and Difference Equations ll6
2.4.l Linear Constant-Coefficient Differential Equations ll7
2.4.2 Linear Constant-Coefficient Difference Equations l2l
2.4.3 Block Diagram Representations of First-Order Systems Described by Differential and Difference Equations l24
2.5 Singularity Functions l27
2.5.l The Unit Impulse as an Idealized Short Pulse l28
2.5.2 Defining the Unit Impulse through Convolution l3l
2.5.3 Unit Doublets and Other Singularity Functions l32
2.6 Summary 137
Problems l37
3 FOUBIER SERIES REPRESENTATON OF PERIODIC SIGNALS 177
3.0 Introduction l77
3.l A Historical Perspective l78
3.2 The Response of LTI Systems to Complex Exponentials 182
3.3 Fourier Series Representation of Continuous-Time Periodic Signals l86
3.3.l Linear Combinations of Harmonically Related Complex Exponentials l86
3.3.2 Determination of the Fourier Series Representation of a Continuous-Time Periodic Signal l90
3.4 Convergence of the Fourier Series l95
3.5 Properties of Continuous-Time Fourier Series 202
3.5.1 Linearity 202
3.5.2 Time Shifting 202
3.5.3 Time Reversal 203
3.5.4 Time Scaling 204
3.5.5 Multiplication 204
3.5.6 Conjugation and Conjugate Symmetry 204
3.5.7 Parseval's Relation for Continuous-Time Periodic Signals 205
3.5.8 Summary of Properties of the Continuous-Time Fourier Series 205
3.5.9 Examples 205
3.6 Fourier Series Representation of Discrete-Time Periodic Signals 211
3.6.l Linear Combinations of Harmonica11y Related Complex Exponentials 21l
3.6.2 Determination of the Fourier Series Representation of a Periodic Signal 2l2
3.7 Properties of Discrete-Time Fourier Series 221
3.7.l Multiplication 222
3.7.2 First Difference 222
3.7.3 Parseval's Relation for Discrete-Time Periodic Signals 223
3.7.4 Examp1es 223
3.8 Fourier Series and LTI Systems 226
3.9 Filtering 23l
3.9.l Frequency--Shaping Filters 232
3.9.2 Frequency Selective Filters 236
3.10 Examples of Continuous-Time Filt6rs Described by Differential Equations 239
3.l0.l A Simple RC Lowpass Filter 239
3.10.2 A Simple RC Highpass Fi1ter 241
3.11 Examples of Discrete-Time Filters Described by Difference Equations 244
3.11.l First-Order Recursive Discrete-Time Filters 244
3.l1.2 Nonrecursive Discrete-Time Filters 245
3.12 Summary 249
Problems 250
4 THE CONTINUOUS-TIME FOURIER TRANSFORM 284
4.0 Introduction 284
4.1 Representation of Aperiodic Signals: The Continuous-Time Fourier Transform 285
4.1.l Development of the Fourier Transform Representation of an Aperiodic Signal 285
4.1.2 Convergence of Fourier Transforms 289
4.1.3 Examples of Continuous-Time Fourier Transforms 290
4.2 The Fourier Transform for Periodic Signals 296
4.3 Properties of the Continuous-Time Fourier Transform 300
4.3.l Linearity 30l
4.3.2 Time Shifting 30l
4.3.3 Conjugation and Conjugate Symmetry 303
4.3.4 Differentiation and Integration 306
4.3.5 Time and Frequency Scaling 308
4.3.6 Duality 309
4.3.7 Parseval's Relation 3l2
4.4 The Convolution Property 3l4
4.4.l Examples 3l7
4.5 The Multiplication Property 322
4.5.l Frequency-Selective Filtering with Variab1e Center Frequency 325
4.6 Tables of Fourier Properties and Of Basic Fourier Transform Pairs 328
4.7 Systems Characterized by Linear Constant-Coefficient Differential Equations 330
4.8 Summary 333
Problems 334
5 THE DISCRETE-TIME FOURIER TRANSFORM 358
5.0 Introduction 358
5.l Representation of Aperiodic Signals: The Discrete-Time Fourier Transform 359
5.1.l Development of the Discrete-Time Fourier Transform 359
5.1.2 Examples of Discrete-Time Fourier Transforms 362
5.l.3 Convergence Issues Associated with the Discrete-Time Fourier Transform 366
5.2 The Fourier Transform for Periodic Signals 367
5.3 Properties of the Discrete-Time Fourier Transform 372
5.3.l Periodicity of the Discrete-Time Fourier Transform 373
5.3.2 Linearity of the Fourier Transform 373
5.3.3 Time Shifting and Frequency Shifting 373
5.3.4 Conjugation and Conjugate Symmetry 375
5.3.5 Differencing and Accumulation 375
5.3.6 Time Reversal 376
5.3.7 Time Expansion 377
5.3.8 Differentiation in Frequency 380
5.3.9 Parseval's Relation 380
5.4 The Convolution Property 382
5.4.l Examples 383
5.5 The Multiplication Property 388
5.6 Tables of Fourier Transform Properties and Basic Fourier Transform Pairs 390
5.7 Duality 390
5.7.1 Duality in the Discrete-Time Fourier Series 39l
5.7.2 Dua1ity between the Discrete-Time Fourier Transform and the Continuous-Time Fourier Series 395
5.8 Systems Characterized by Linear Constant-Coefficient Difference Equations 396
5.9 Summary 399
Problems 400
6 TIME AND FREQUENCY CHARACTERIZATION OF SIGNALS AND SYSTEMS 423
6.0 Introduction 423
6.1 The Magnitude-Phase Representation of the Fourier Transform 423
6.2 The Magnitude-Phase Representation of the Frequency Response of LTI Systems 427
6.2.l Linear and Non1inear Phase 428
6.2.2 Group De1ay 430
6.2.3 Log-Magnitude and Bode Plots 436
6.3 Time-Domain Properties of Ideal Frequency-Selective Filters as9
6.4 Time-Domain and Frequency-Domain Aspects of Nonideal Filters
6.5 First-Order and Second-Order Continuous-Time Systems 448
6.5.l First-Order Continuous-Time Systems 448
6.5.2 Second-Order Continuous--Time Systems 45l
6.5.3 Bode Plots for Rational Frequency Responses 456
6.6 First-Order and Second-Order Discrete-Time Systems 461
6.6.l First-Order Discrete-Time Systems 46l
6.6.2 Second-Order Discrete-Time Systems 465
6.7 Examples of Time-and Frequency-Domain Analysis Of Systems 472
6.7.1 Analysis of an Automobile Suspension System 473
6.7.2 Examples of Discrete-Time Nonrecursive Filters 476
6.8 Summary 482
Problems 483
7 SAMPLING 514
7.0 Introduction 5l4
7.1 Representation of a Continuous-Time Signal by Its Samples: The Sampling Theorem 515
7.1.l Impulse-Train Sampling 5l6
7.l.2 Sampling with a Zero-Order Hold 520
7.2 Reconstruction of a Signal from Its Samples Using Interpolation 522
7.3 The Effect Of Undersampling: Aliasing 527
7.4 Discrete-Time Processing of Continuous-Time Signals 534
7.4.1 Digital Differentiator 54l
7.4.2 Half Sample Delay 543
7.5 Sampling of Discrete-Time Signals 545
7.5.l Impulse-Train Sampling 545
7.5.2 Discrete-Time Decimation and Interpolation 549
7.6 Summary 555
Problems 556
8 COMMUNICATION SYSTEMS 582
8.0 Introduction 582
8.l Complex Exponential and Sinusoidal Amplitude Modulation 583
8.l.1 Amplitude Modulation with a Complex Exponential Carrier 583
8.l.2 Amplitude Modulation with a Sinusoidal Carrier 585
8.2 Demodulation for Sinusoidal AM 587
8.2.l Synchronous Demodulation 587
8.2.2 Asynchronous Demodulation 590
8.3 Frequency-Division Multiplexing 594
8.4 Single-Sideband Sinusoidal Amplitude Modulation 597
8.5 Amplitude Modulation with a Pulse-Train Carrier 601
8.5.l Modulation of a Pulse-Train Carrier 60l
8.5.2 Time-Division Multiplexing 604
8.6 Pulse-Amplitude Modulation 604
8.6.l Pulse-Amplitude Modulated Signals 604
8.6.2 Intersymbol Interference in PAM Systems 607
8.6.3 Digital Pulse-Amplitude and Pulse-Code Modulation 610
8.7 Sinusoidal Frequency Modulation 61l
8.7.l Narrowband Frequency Modulation 6l3
8.7.2 Wideband Frequency Modulation 6l5
8.7.3 Periodic Square-Wave Modulating Signal 617
8.8 Discrete-Time Modulation 6l9
8.8.l Discrete-Time Sinusoidal Amplitude Modulation 619
8.8.2 Discrete-Time Transmodulation 623
8.9 Summary 623
Problems 625
9 THE LAPLACE TRANSFORM 654
9.0 Introduction 654
9.l The Laplace Transform 655
9.2 The Region of Convergence for Laplace Transforms 662
9.3 The Inverse Laplace Transform 670
9.4 Geometric Evaluation of the Fourier Transform from the Pole-Zero Plot 674
9.4.l First-Order Systems 676
9.4.2 Second--Order Systems 677
9.4.3 All-Pass Systems 68l
9.5 Properties Of the Laplace Transform 682
9.5.l Linearity of the Laplace Transform 683
9.5.2 Time Shifting 684
9.5.3 Shifting in the s-Domain 685
9.5.4 Time Sca1ing 685
9.5.5 Conjugation 687
9.5.6 Convolution Property 687
9.5.7 Differentiation in the Time Domain 688
9.5.8 Differentiation in the s-Domain 688
9.5.9 Integration in the Time Domain 690
9.5.l0 The Initial- and Final-Value Theorems 690
9.5.l1 Table of Properties 691
9.6 Some Laplace Transform Pairs 692
9.7 Analysis and Characterization Of LTI Systems Using the Laplace Transform 693
9.7.1 Causality 693
9.7.2 Stability 695
9.7.3 LTI Systems Characterization by Linear Constant-Coefficient Differential Equations 698
9.7.4 Examples Relating System Behavior to the System Function 70l
9.7.5 Butterworth Filters 703
9.8 System Function Algebra and Block Diagram Representations 706
9.8.l System Functions for Interconnections of LTI Systems 707
9.8.2 Block Diagram Representations for Causal LTI Systems Described by Differential Equations and Rational System Functions 708
9.9 The Unilateral Laplate Transform 714
9.9.1 Examples of Unilateral Laplace Transforms 714
9.9.2 Properties of the Unilateral Laplace Transform 7l6
9.9.3 Solving Differential Equations Using the Unilateral Laplace Transform 719
9.10 Summary 720
Problems 72l
10 THE Z--TRANSFORM 741
l0.0 Introduction 741
10.1 The-Transform 741
l0.2 The Region Of Convergence for the z-Transform 748
l0.3 The Inverse z-Transform 757
l0.4 Geometric Evaluation of the Fourier Transform from the Pole-Zero Plot 763
l0.4.l First-Order Systems 763
l0.4.2 Second-Order Systems 765
l0.5 Properties of the z-Transform 767
l0.5.l Linearity 767
10.5.2 Time Shifting 767
10.5.3 Scaling in the z-Domain 768
l0.5.4 Time Reversal 769
l0.5.5 Time Expansion 769
l0.5.6 Conjugation 770
l0.5.7 The Convolution Property 770
l0.5.8 Differentiation in the z-Domain 772
l0.5.9 The Initial--Value Theorem 773
l0.5.l0 Summary of Properties 774
l0.6 Some Common z-Transform Pairs 774
l0.7 Analysis and Charact6rization Of LTI Systems Using z-Transforms 774
10.7.l Causality 776
l0.7.2 Stability 777
10.7.3 LTI Systems Characterized by Linear Constant-Coefficient Difference Equations 779
l0.7.4 Examples Relating System Behavior to the System Function 78
l0.8 System Function Algebra and Block Diagram
Representations 783
l0.8.1 System Functions for Interconnections of LTI Systems 784
l0.8.2 Block Diagram Representations for Causal LTI Systems Described by Difference Equations and Rational System Functions 784
l0.9 The Unilateral z-Transform 789
l0.9.l Examp1es of Unilatera1 z-Transforms and Inverse Transforms 790
l0.9.2 Properties of the Unilatera1 z-Transform 792
l0.9.3 Solving Difference Equations Using the Unilateral z-Transform 795
l0.l0 Summary 796
Problems 797
11 LINEAR FEEDBACK SYSTEMS 816
ll.0 Introduction 816
ll.1 Linear Feedback Systems 819
l1.2 Some Applications and Consequences of Feedback 820
ll.2.l Inverse System Design 820
ll.2.2 Compensation for Nonideal E1ements 82l
ll.2.3 Stabilization of Unstable Systems 823
ll.2.4 Sampled-Data Feedback Systems 826
ll.2.5 Tracking Systems 828
11.2.6 Destabilization Caused by Feedback 830
ll.3 Root-Locus Analysis Of Linear Feedback Systems 832
l1.3.l An Introductory Example 833
ll.3.2 Equation for the Closed-Loop Poles 834
ll.3.3 The End Points of the Root Locus: The Closed-Loop Poles for K=0 and |K| = + 836
ll.3.4 The Angle Criterion 836
11.3.5 Properties of the Root Locus 841
1l.4 The Nyquist Stability Criterion 846
ll.4.l The Encirclement Property 847
l1.4.2 The Nyquist Criterion for Continuous-Time LTI Feedback Systems 850
1l.4.3 The Nyquist: Criterion for Discrete--Time LTI Feedback Systems 856
11.5 Gain and Phase Margins 858
11.6 Summary 866
Problems 867
APPENDIX PARTIAL-FRACTION EXPANSION 909
BIBLIOGRAPHY 921
ANSWERS 93l
INDEX 941
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