Understanding GPS Principles and Applications, Second Edition
1st Edition
Published on 1. January 2005
726 pages
978-1-58053-895-4 (ISBN)
Description
This thoroughly updated second edition of an Artech House bestseller brings together a team of leading experts who provide you with a current and comprehensive treatment of the Global Positioning System (GPS). The book covers all the latest advances in technology, applications, and systems. The second edition includes new chapters that explore the integration of GPS with vehicles and cellular telephones, new classes of satellite broadcast signals, the emerging GALILEO system, and new developments in the GPS marketplace.
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12/2006
2nd Edition
Artech House Publishers
€165.50
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Content
- Intro
- Contents
- Preface xv
- Acknowledgments xvii
- 1 Introduction 1
- 1.1 Introduction 1
- 1.2 Condensed GPS Program History 2
- 1.3 GPS Overview 3
- 1.3.1 PPS 4
- 1.3.2 SPS 4
- 1.4 GPS Modernization Program 5
- 1.5 GALILEO Satellite System 6
- 1.6 Russian GLONASS System 7
- 1.7 Chinese BeiDou System 8
- 1.8 Augmentations 10
- 1.9 Markets and Applications 10
- 1.9.1 Land 11
- 1.9.2 Aviation 12
- 1.9.3 Space Guidance 13
- 1.9.4 Maritime 14
- 1.10 Organization of the Book 14
- References 19
- 2 Fundamentals of Satellite Navigation 21
- 2.1 Concept of Ranging Using TOA Measurements 21
- 2.1.1 Two-Dimensional Position Determination 21
- 2.1.2 Principle of Position Determination Via Satellite-Generated Ranging Signals 24
- 2.2 Reference Coordinate Systems 26
- 2.2.1 Earth-Centered Inertial Coordinate System 27
- 2.2.2 Earth-Centered Earth-Fixed Coordinate System 28
- 2.2.3 World Geodetic System 29
- 2.2.4 Height Coordinates and the Geoid 32
- 2.3 Fundamentals of Satellite Orbits 34
- 2.3.1 Orbital Mechanics 34
- 2.3.2 Constellation Design 43
- 2.4 Position Determination Using PRN Codes 50
- 2.4.1 Determining Satellite-to-User Range 51
- 2.4.2 Calculation of User Position 54
- 2.5 Obtaining User Velocity 58
- 2.6 Time and GPS 61
- 2.6.1 UTC Generation 61
- 2.6.2 GPS System Time 62
- 2.6.3 Receiver Computation of UTC (USNO) 62
- References 63
- 3 GPS System Segments 67
- 3.1 Overview of the GPS System 67
- 3.1.1 Space Segment Overview 67
- 3.1.2 Control Segment (CS) Overview 68
- 3.1.3 User Segment Overview 68
- 3.2 Space Segment Description 68
- 3.2.1 GPS Satellite Constellation Description 69
- 3.2.2 Constellation Design Guidelines 71
- 3.2.3 Space Segment Phased Development 71
- 3.3 Control Segment 87
- 3.3.1 Current Configuration 88
- 3.3.2 CS Planned Upgrades 100
- 3.4 User Segment 103
- 3.4.1 GPS Set Characteristics 103
- 3.4.2 GPS Receiver Selection 109
- References 110
- 4 GPS Satellite Signal Characteristics 113
- 4.1 Overview 113
- 4.2 Modulations for Satellite Navigation 113
- 4.2.1 Modulation Types 113
- 4.2.2 Multiplexing Techniques 115
- 4.2.3 Signal Models and Characteristics 116
- 4.3 Legacy GPS Signals 123
- 4.3.1 Frequencies and Modulation Format 123
- 4.3.2 Power Levels 133
- 4.3.3 Autocorrelation Functions and Power Spectral Densities 135
- 4.3.4 Cross-Correlation Functions and CDMA Performance 140
- 4.4 Navigation Message Format 142
- 4.5 Modernized GPS Signals 145
- 4.5.1 L2 Civil Signal 145
- 4.5.2 L5 147
- 4.5.3 M Code 148
- 4.5.4 L1 Civil Signal 150
- 4.6 Summary 150
- References 150
- 5 Satellite Signal Acquisition, Tracking, and Data Demodulation 153
- 5.1 Overview 153
- 5.2 GPS Receiver Code and Carrier Tracking 155
- 5.2.1 Predetection Integration 158
- 5.2.2 Baseband Signal Processing 159
- 5.2.3 Digital Frequency Synthesis 161
- 5.2.4 Carrier Aiding of Code Loop 162
- 5.2.5 External Aiding 164
- 5.3 Carrier Tracking Loops 164
- 5.3.1 Phase Lock Loops 165
- 5.3.2 Costas Loops 166
- 5.3.3 Frequency Lock Loops 170
- 5.4 Code Tracking Loops 173
- 5.5 Loop Filters 179
- 5.6 Measurement Errors and Tracking Thresholds 183
- 5.6.1 PLL Tracking Loop Measurement Errors 184
- 5.6.2 FLL Tracking Loop Measurement Errors 192
- 5.6.3 C/A and P(Y) Code Tracking Loop Measurement Errors 194
- 5.6.4 Modernized GPS M Code Tracking Loop Measurement Errors 199
- 5.7 Formation of Pseudorange, Delta Pseudorange, and Integrated Doppler 200
- 5.7.1 Pseudorange 201
- 5.7.2 Delta Pseudorange 216
- 5.7.3 Integrated Doppler 218
- 5.8 Signal Acquisition 219
- 5.8.1 Tong Search Detector 223
- 5.8.2 M of N Search Detector 227
- 5.8.3 Direct Acquisition of GPS Military Signals 229
- 5.9 Sequence of Initial Receiver Operations 231
- 5.10 Data Demodulation 232
- 5.11 Special Baseband Functions 233
- 5.11.1 Signal-to-Noise Power Ratio Meter 233
- 5.11.2 Phase Lock Detector with Optimistic and Pessimistic Decisions 233
- 5.11.3 False Frequency Lock and False Phase Lock Detector 235
- 5.12 Use of Digital Processing 235
- 5.13 Considerations for Indoor Applications 237
- 5.14 Codeless and Semicodeless Processing 239
- References 240
- 6 Interference, Multipath, and Scintillation 243
- 6.1 Overview 243
- 6.2 Radio Frequency Interference 243
- 6.2.1 Types and Sources of RF Interference 244
- 6.2.2 Effects of RF Interference on Receiver Performance 247
- 6.2.3 Interference Mitigation 278
- 6.3 Multipath 279
- 6.3.1 Multipath Characteristics and Models 281
- 6.3.2 Effects of Multipath on Receiver Performance 285
- 6.3.3 Multipath Mitigation 292
- 6.4 Ionospheric Scintillation 295
- References 297
- 7 Performance of Stand-Alone GPS 301
- 7.1 Introduction 301
- 7.2 Measurement Errors 302
- 7.2.1 Satellite Clock Error 304
- 7.2.2 Ephemeris Error 305
- 7.2.3 Relativistic Effects 306
- 7.2.4 Atmospheric Effects 308
- 7.2.5 Receiver Noise and Resolution 319
- 7.2.6 Multipath and Shadowing Effects 319
- 7.2.7 Hardware Bias Errors 320
- 7.2.8 Pseudorange Error Budgets 321
- 7.3 PVT Estimation Concepts 322
- 7.3.1 Satellite Geometry and Dilution of Precision in GPS 322
- 7.3.2 Accuracy Metrics 328
- 7.3.3 Weighted Least Squares (WLS) 332
- 7.3.4 Additional State Variables 333
- 7.3.5 Kalman Filtering 334
- 7.4 GPS Availability 334
- 7.4.1 Predicted GPS Availability Using the Nominal 24-Satellite GPS Constellation 335
- 7.4.2 Effects of Satellite Outages on GPS Availability 337
- 7.5 GPS Integrity 343
- 7.5.1 Discussion of Criticality 345
- 7.5.2 Sources of Integrity Anomalies 345
- 7.5.3 Integrity Enhancement Techniques 346
- 7.6 Continuity 360
- 7.7 Measured Performance 361
- References 375
- 8 Differential GPS 379
- 8.2 Spatial and Time Correlation Characteristics of GPS Errors 381
- 8.2.1 Satellite Clock Errors 381
- 8.2.2 Ephemeris Errors 382
- 8.2.3 Tropospheric Errors 384
- 8.2.4 Ionospheric Errors 387
- 8.2.5 Receiver Noise and Multipath 390
- 8.3 Code-Based Techniques 391
- 8.3.1 Local-Area DGPS 391
- 8.3.2 Regional-Area DGPS 394
- 8.3.3 Wide-Area DGPS 395
- 8.4 Carrier-Based Techniques 397
- 8.4.1 Precise Baseline Determination in Real Time 398
- 8.4.2 Static Application 418
- 8.4.3 Airborne Application 420
- 8.4.4 Attitude Determination 423
- 8.5 Message Formats 425
- 8.5.1 Version 2.3 425
- 8.5.2 Version 3.0 428
- 8.6 Examples 429
- 8.6.2 Carrier Based 450
- References 454
- 9 Integration of GPS with Other Sensors and Network Assistance 459
- 9.1 Overview 459
- 9.2 GPS/Inertial Integration 460
- 9.2.1 GPS Receiver Performance Issues 460
- 9.2.2 Inertial Sensor Performance Issues 464
- 9.2.3 The Kalman Filter 466
- 9.2.4 GPSI Integration Methods 470
- 9.2.5 Reliability and Integrity 488
- 9.2.6 Integration with CRPA 489
- 9.3 Sensor Integration in Land Vehicle Systems 491
- 9.3.1 Introduction 491
- 9.3.2 Review of Available Sensor Technology 496
- 9.3.3 Sensor Integration Principles 515
- 9.4 Network Assistance 522
- 9.4.1 Historical Perspective of Assisted GPS 526
- 9.4.2 Requirements of the FCC Mandate 528
- 9.4.3 Total Uncertainty Search Space 535
- 9.4.4 GPS Receiver Integration in Cellular Phones-Assistance Data from Handsets 540
- 9.4.5 Types of Network Assistance 543
- References 554
- 10 GALILEO 559
- 10.1 GALILEO Program Objectives 559
- 10.2 GALILEO Services and Performance 559
- 10.2.1 Open Service (OS) 560
- 10.2.2 Commercial Service (CS) 562
- 10.2.3 Safety of Life (SOL) Service 562
- 10.2.4 Public Regulated Service (PRS) 562
- 10.2.5 Support to Search and Rescue (SAR) Service 563
- 10.3 GALILEO Frequency Plan and Signal Design 563
- 10.3.1 Frequencies and Signals 563
- 10.3.2 Modulation Schemes 565
- 10.3.3 SAR Signal Plan 576
- 10.4 Interoperability Between GPS and GALILEO 577
- 10.4.1 Signal in Space 577
- 10.4.2 Geodetic Coordinate Reference Frame 578
- 10.4.3 Time Reference Frame 578
- 10.5 System Architecture 579
- 10.5.1 Space Segment 581
- 10.5.2 Ground Segment 585
- 10.6 GALILEO SAR Architecture 591
- 10.7 GALILEO Development Plan 592
- References 594
- 11 Other Satellite Navigation Systems 595
- 11.1 The Russian GLONASS System 595
- 11.1.1 Introduction 595
- 11.1.2 Program Overview 595
- 11.1.3 Organizational Structure 597
- 11.1.4 Constellation and Orbit 597
- 11.1.5 Spacecraft Description 599
- 11.1.6 Ground Support 602
- 11.1.7 User Equipment 604
- 11.1.8 Reference Systems 605
- 11.1.9 GLONASS Signal Characteristics 606
- 11.1.10 System Accuracy 611
- 11.1.11 Future GLONASS Development 612
- 11.1.12 Other GLONASS Information Sources 614
- 11.2 The Chinese BeiDou Satellite Navigation System 615
- 11.2.1 Introduction 615
- 11.2.3 Program History 616
- 11.2.4 Organization Structure 617
- 11.2.5 Constellation and Orbit 617
- 11.2.6 Spacecraft 617
- 11.2.7 RDSS Service Infrastructure 618
- 11.2.8 RDSS Navigation Services 621
- 11.2.9 RDSS Navigation Signals 622
- 11.2.10 System Coverage and Accuracy 623
- 11.2.11 Future Developments 623
- 11.3 The Japanese QZSS Program 625
- 11.3.1 Introduction 625
- 11.3.2 Program Overview 625
- 11.3.3 Organizational Structure 626
- 11.3.4 Constellation and Orbit 626
- 11.3.5 Spacecraft Development 627
- 11.3.6 Ground Support 628
- 11.3.7 User Equipment 628
- 11.3.8 Reference Systems 628
- 11.3.9 Navigation Services and Signals 628
- 11.3.10 System Coverage and Accuracy 629
- 11.3.11 Future Development 629
- Acknowledgments 630
- References 630
- 12 GNSS Markets and Applications 635
- 12.1 GNSS: A Complex Market Based on Enabling Technologies 635
- 12.1.1 Market Scope, Segmentation, and Value 638
- 12.1.2 Unique Aspects of GNSS Market 639
- 12.1.3 Market Limitations, Competitive Systems, and Policy 640
- 12.2 Civil Navigation Applications of GNSS 641
- 12.2.1 Marine Navigation 642
- 12.2.2 Air Navigation 645
- 12.2.3 Land Navigation 646
- 12.3 GNSS in Surveying, Mapping, and Geographical Information Systems 647
- 12.3.1 Surveying 648
- 12.3.2 Mapping 648
- 12.3.3 GIS 649
- 12.4 Recreational Markets for GNSS-Based Products 650
- 12.5 GNSS Time Transfer 650
- 12.6 Differential Applications and Services 650
- 12.6.1 Precision Approach Aircraft Landing Systems 651
- 12.6.2 Other Differential Systems 651
- 12.6.3 Attitude Determination Systems 652
- 12.7 GNSS and Telematics and LBS 652
- 12.8 Creative Uses for GNSS 654
- 12.9 Government and Military Applications 654
- 12.9.1 Military User Equipment-Aviation, Shipboard, and Land 655
- 12.9.2 Autonomous Receivers-Smart Weapons 656
- 12.9.3 Space Applications 657
- 12.9.4 Other Government Applications 657
- 12.10 User Equipment Needs for Specific Markets 657
- 12.11 Financial Projections for the GNSS Industry 660
- References 661
- Appendix A:Least Squares and Weighted Least Squares Estimates 663
- Reference 664
- Appendix B:Stability Measures for Frequency Sources 665
- B.1 Introduction 665
- B.2 Frequency Standard Stability 665
- B.3 Measures of Stability 667
- B.3.1 Allan Variance 667
- B.3.2 Hadamard Variance 667
- References 668
- Appendix C:Free-Space Propagation Loss 669
- C.1 Introduction 669
- C.2 Free-Space Propagation Loss 669
- C.3 Conversion Between PSDs and PFDs 673
- References 673
- About the Authors 675
- Index 683
- Mobile Communications Library
