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GPS Satellite Surveying

2017-06-30 
Employ the latest satellite positioning tech with this extensive guideGPS Satellite Surveying is the
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GPS Satellite Surveying

Employ the latest satellite positioning tech with this extensive guide

GPS Satellite Surveying is the classic text on the subject, providing the most comprehensive coverage of global navigation satellite systems applications for surveying. Fully updated and expanded to reflect the field's latest developments, this new edition contains new information on GNSS antennas, Precise Point Positioning, Real-time Relative Positioning, Lattice Reduction, and much more. New contributors offer additional insight that greatly expands the book's reach, providing readers with complete, in-depth coverage of geodetic surveying using satellite technologies. The newest, most cutting-edge tools, technologies, and applications are explored in-depth to help readers stay up to date on best practices and preferred methods, giving them the understanding they need to consistently produce more reliable measurement.

Global navigation satellite systems have an array of uses in military, civilian, and commercial applications. In surveying, GNSS receivers are used to position survey markers, buildings, and road construction as accurately as possible with less room for human error. GPS Satellite Surveying provides complete guidance toward the practical aspects of the field, helping readers to:

Get up to speed on the latest GPS/GNSS developments Understand how satellite technology is applied to surveying Examine in-depth information on adjustments and geodesy Learn the fundamentals of positioning, lattice adjustment, antennas, and more

The surveying field has seen quite an evolution of technology in the decade since the last edition's publication. This new edition covers it all, bringing the reader deep inside the latest tools and techniques being used on the job. Surveyors, engineers, geologists, and anyone looking to employ satellite positioning will find GPS Satellite Surveying to be of significant assistance.

作者简介

ALFRED LEICK, PHD, has served on the Board of Directors of the American Association of Geodetic Surveying. He currently lectures at Michigan Technological University and is the Editor-in-Chief of scholarly journal GPS Solutions.

LEV RAPOPORT, PHD, received Russia's highest scientific degree, Doctor of Science, from the Institute of Control Sciences of the Russian Academy of Science, where he is now head of laboratory. He is also a professor at the Moscow Institute of Physics and Technology.

DMITRY TATARNIKOV, PHD, received the Doctor of Science degree from Moscow Aviation Institute, where he is currently a professor. He is also the Chief of GNSS Antenna Design and Development for Topcon Technology Center.

目录

PREFACE xv

ACKNOWLEDGMENTS xix

ABBREVIATIONS xxi

1 INTRODUCTION 1

2 LEAST-SQUARES ADJUSTMENTS 11

2.1 Elementary Considerations 12

2.1.1 Statistical Nature of Surveying Measurements 12

2.1.2 Observational Errors 13

2.1.3 Accuracy and Precision 13

2.2 Stochastic and Mathematical Models 14

2.3 Mixed Model 17

2.3.1 Linearization 18

2.3.2 Minimization and Solution 19

2.3.3 Cofactor Matrices 20

2.3.4 A Posteriori Variance of Unit Weight 21

2.3.5 Iterations 22

2.4 Sequential Mixed Model 23

2.5 Model Specifications 29

2.5.1 Observation Equation Model 29

2.5.2 Condition Equation Model 30

2.5.3 Mixed Model with Observation Equations 30

2.5.4 Sequential Observation Equation Model 32

2.5.5 Observation Equation Model with Observed Parameters 32

2.5.6 Mixed Model with Conditions 34

2.5.7 Observation Equation Model with Conditions 35

2.6 Minimal and Inner Constraints 37

2.7 Statistics in Least-Squares Adjustment 42

2.7.1 Fundamental Test 42

2.7.2 Testing Sequential Least Squares 48

2.7.3 General Linear Hypothesis 49

2.7.4 Ellipses as Confidence Regions 52

2.7.5 Properties of Standard Ellipses 56

2.7.6 Other Measures of Precision 60

2.8 Reliability 62

2.8.1 Redundancy Numbers 62

2.8.2 Controlling Type-II Error for a Single Blunder 64

2.8.3 Internal Reliability 67

2.8.4 Absorption 67

2.8.5 External Reliability 68

2.8.6 Correlated Cases 69

2.9 Blunder Detection 70

2.9.1 Tau Test 71

2.9.2 Data Snooping 71

2.9.3 Changing Weights of Observations 72

2.10 Examples 72

2.11 Kalman Filtering 77

3 RECURSIVE LEAST SQUARES 81

3.1 Static Parameter 82

3.2 Static Parameters and Arbitrary Time-Varying Variables 87

3.3 Dynamic Constraints 96

3.4 Static Parameters and Dynamic Constraints 112

3.5 Static Parameter, Parameters Subject to Dynamic Constraints, and Arbitrary Time-Varying Parameters 125

4 GEODESY 129

4.1 International Terrestrial Reference Frame 131

4.1.1 Polar Motion 132

4.1.2 Tectonic Plate Motion 133

4.1.3 Solid Earth Tides 135

4.1.4 Ocean Loading 135

4.1.5 Relating of Nearly Aligned Frames 136

4.1.6 ITRF and NAD83 138

4.2 International Celestial Reference System 141

4.2.1 Transforming Terrestrial and Celestial Frames 143

4.2.2 Time Systems 149

4.3 Datum 151

4.3.1 Geoid 152

4.3.2 Ellipsoid of Rotation 157

4.3.3 Geoid Undulations and Deflections of the Vertical 158

4.3.4 Reductions to the Ellipsoid 162

4.4 3D Geodetic Model 166

4.4.1 Partial Derivatives 169

4.4.2 Reparameterization 170

4.4.3 Implementation Considerations 171

4.4.4 GPS Vector Networks 174

4.4.5 Transforming Terrestrial and Vector Networks 176

4.4.6 GPS Network Examples 178

4.5 Ellipsoidal Model 190

4.5.1 Reduction of Observations 191

4.5.2 Direct and Inverse Solutions on the Ellipsoid 195

4.5.3 Network Adjustment on the Ellipsoid 196

4.6 Conformal Mapping Model 197

4.6.1 Reduction of Observations 198

4.6.2 Angular Excess 200

4.6.3 Direct and Inverse Solutions on the Map 201

4.6.4 Network Adjustment on the Map 201

4.6.5 Similarity Revisited 203

4.7 Summary 204

5 SATELLITE SYSTEMS 207

5.1 Motion of Satellites 207

5.1.1 Kepler Elements 208

5.1.2 Normal Orbital Theory 210

5.1.3 Satellite Visibility and Topocentric Motion 219

5.1.4 Perturbed Satellite Motion 219

5.2 Global Positioning System 225

5.2.1 General Description 226

5.2.2 Satellite Transmissions at 2014 228

5.2.3 GPS Modernization Comprising Block IIM, Block IIF, and Block III 239

5.3 GLONASS 245

5.4 Galileo 248

5.5 QZSS 250

5.6 Beidou 252

5.7 IRNSS 254

5.8 SBAS: WAAS, EGNOS, GAGAN, MSAS, and SDCM 254

6 GNSS POSITIONING APPROACHES 257

6.1 Observables 258

6.1.1 Undifferenced Functions 261

6.1.2 Single Differences 271

6.1.3 Double Differences 273

6.1.4 Triple Differences 275

6.2 Operational Details 275

6.2.1 Computing the Topocentric Range 275

6.2.2 Satellite Timing Considerations 276

6.2.3 Cycle Slips 282

6.2.4 Phase Windup Correction 283

6.2.5 Multipath 286

6.2.6 Phase Center Offset and Variation 292

6.2.7 GNSS Services 295

6.3 Navigation Solution 299

6.3.1 Linearized Solution 299

6.3.2 DOPs and Singularities 301

6.3.3 Nonlinear Closed Solution 303

6.4 Relative Positioning 304

6.4.1 Nonlinear Double-Difference Pseudorange Solution 305

6.4.2 Linearized Double- and Triple-Differenced Solutions 306

6.4.3 Aspects of Relative Positioning 310

6.4.4 Equivalent Undifferenced Formulation 315

6.4.5 Ambiguity Function 316

6.4.6 GLONASS Carrier Phase 319

6.5 Ambiguity Fixing 324

6.5.1 The Constraint Solution 324

6.5.2 LAMBDA 327

6.5.3 Discernibility 334

6.5.4 Lattice Reduction and Integer Least Squares 337

6.6 Network-Supported Positioning 357

6.6.1 PPP 357

6.6.2 CORS 363

6.6.3 PPP-RTK 367

6.7 Triple-Frequency Solutions 382

6.7.1 Single-Step Position Solution 382

6.7.2 Geometry-Free TCAR 386

6.7.3 Geometry-Based TCAR 395

6.7.4 Integrated TCAR 396

6.7.5 Positioning with Resolved Wide Lanes 397

6.8 Summary 398

7 REAL-TIME KINEMATICS RELATIVE POSITIONING 401

7.1 Multisystem Considerations 402

7.2 Undifferenced and Across-Receiver Difference Observations 403

7.3 Linearization and Hardware Bias Parameterization 408

7.4 RTK Algorithm for Static and Short Baselines 418

7.4.1 Illustrative Example 422

7.5 RTK Algorithm for Kinematic Rovers and Short Baselines 429

7.5.1 Illustrative Example 431

7.6 RTK Algorithm with Dynamic Model and Short Baselines 435

7.6.1 Illustrative Example 437

7.7 RTK Algorithm with Dynamic Model and Long Baselines 441

7.7.1 Illustrative Example 442

7.8 RTK Algorithms with Changing Number of Signals 445

7.9 Cycle Slip Detection and Isolation 450

7.9.1 Solutions Based on Signal Redundancy 455

7.10 Across-Receiver Ambiguity Fixing 466

7.10.1 Illustrative Example 470

7.11 Software Implementation 473

8 TROPOSPHERE AND IONOSPHERE 475

8.1 Overview 476

8.2 Tropospheric Refraction and Delay 479

8.2.1 Zenith Delay Functions 482

8.2.2 Mapping Functions 482

8.2.3 Precipitable Water Vapor 485

8.3 Troposphere Absorption 487

8.3.1 The Radiative Transfer Equation 487

8.3.2 Absorption Line Profiles 490

8.3.3 General Statistical Retrieval 492

8.3.4 Calibration of WVR 494

8.4 Ionospheric Refraction 496

8.4.1 Index of Ionospheric Refraction 499

8.4.2 Ionospheric Function and Cycle Slips 504

8.4.3 Single-Layer Ionospheric Mapping Function 505

8.4.4 VTEC from Ground Observations 507

8.4.5 Global Ionospheric Maps 509

9 GNSS RECEIVER ANTENNAS 513

9.1 Elements of Electromagnetic Fields and Electromagnetic Waves 515

9.1.1 Electromagnetic Field 515

9.1.2 Plane Electromagnetic Wave 518

9.1.3 Complex Notations and Plane Wave in Lossy Media 525

9.1.4 Radiation and Spherical Waves 530

9.1.5 Receiving Mode 536

9.1.6 Polarization of Electromagnetic Waves 537

9.1.7 The dB Scale 544

9.2 Antenna Pattern and Gain 546

9.2.1 Receiving GNSS Antenna Pattern and Reference Station and Rover Antennas 546

9.2.2 Directivity 553

9.2.3 Polarization Properties of the Receiving GNSS Antenna 558

9.2.4 Antenna Gain 562

9.2.5 Antenna Effective Area 564

9.3 Phase Center 565

9.3.1 Antenna Phase Pattern 566

9.3.2 Phase Center Offset and Variations 568

9.3.3 Antenna Calibrations 575

9.3.4 Group Delay Pattern 577

9.4 Diffraction and Multipath 578

9.4.1 Diffraction Phenomena 578

9.4.2 General Characterization of Carrier Phase Multipath 585

9.4.3 Specular Reflections 587

9.4.4 Antenna Down-Up Ratio 593

9.4.5 PCV and PCO Errors Due to Ground Multipath 597

9.5 Transmission Lines 600

9.5.1 Transmission Line Basics 600

9.5.2 Antenna Frequency Response 606

9.5.3 Cable Losses 608

9.6 Signal-to-Noise Ratio 609

9.6.1 Noise Temperature 609

9.6.2 Characterization of Noise Sources 611

9.6.3 Signal and Noise Propagation through a Chain of Circuits 615

9.6.4 SNR of the GNSS Receiving System 619

9.7 Antenna Types 620

9.7.1 Patch Antennas 620

9.7.2 Other Types of Antennas 629

9.7.3 Flat Metal Ground Planes 629

9.7.4 Impedance Ground Planes 634

9.7.5 Vertical Choke Rings and Compact Rover Antenna 642

9.7.6 Semitransparent Ground Planes 644

9.7.7 Array Antennas 645

9.7.8 Antenna Manufacturing Issues 650

APPENDIXES

A GENERAL BACKGROUND 653

B THE ELLIPSOID 697

C CONFORMAL MAPPING 715

D VECTOR CALCULUS AND DELTA FUNCTION 741

E ELECTROMAGNETIC FIELD GENERATED BY ARBITRARY SOURCES, MAGNETIC CURRENTS, BOUNDARY CONDITIONS, AND IMAGES 747

F DIFFRACTION OVER HALF-PLANE 755

G SINGLE CAVITY MODE APPROXIMATION WITH PATCH ANTENNA ANALYSIS 759

H PATCH ANTENNAS WITH ARTIFICIAL DIELECTRIC SUBSTRATES 763

I CONVEX PATCH ARRAY GEODETIC ANTENNA 769

REFERENCES 773

AUTHOR INDEX 793

SUBJECT INDEX 801

网友对GPS Satellite Surveying的评论

I am delighted to finally see another edition of this classical text on GPS/GNSS. Since the book provides a detailed treatment on adjustments and geodesy, it has been a helpful reference for me for many years while working on high-accuracy GNSS positioning applications.

This fourth edition represents a major expansion and a new arrangement of the topics. It now begins with two adjustment sections, followed by geodesy, and then GPS/GNSS. This arrangement seems more logical and therefore items of interest are easier to find. The number of pages has doubled from about 400 to 800. Basically three major chapters have been added. One of them is a dedicated and stand-alone chapter which is Chapter 3 on Recursive Least Squares. This technique is very suitable for applications when the parameters and the number of parameters changes with time, as occurs when a receiver moves and satellites rise and set. The technique is therefore the basis of the other new chapter, Chapter 7, on real-time RTK. This chapter provides details of, e.g. the combined use of GPS and GLONASS observations at a level of completeness suitable for implementation as receiver software. The last new chapter, Chapter 9, is dedicated to GPS user antennas. This 100+ page treatment of various antenna subjects, apparently the work of a new coauthor and antenna expert, is comprehensive in its content, and is a unique feature in a surveying/geodesy book on GNSS. The material gets to the bottom of multipath, antenna phase pattern, and so on.
Like previous editions, I am sure the 4th edition will maintain the unique slot which the book always had in the GPS/GNSS literature. It remains an invaluable resource for those who need to understand GNSS beyond operating a GNSS receiver, and to those who need to know how GNSS positioning is embedded in geodesy. Interestingly, this new edition maintains the material on conformal mapping, State Plane Coordinate Systems, and continues to feature the 3D geodetic model as the most universal model. Since the book addresses such a rich set of topics in a unified manner it should continue to be of interest to professionals from many disciplines such as surveyors, engineers, geologists, geophysicists, navigators, and GNSS hardware and software developers, last but not least students. Just the new material added makes it worthwhile to get this new edition.
Jeremy S

The 4th edition has become more complete. With the addition of a new chapter on recursive least squares, the book now presents a comprehensive treatment of least squares with a depth equivalent to what is found in dedicated books on that topic. In the new Chapter 7 these recursive least squares formulations are applied to provide a unified and comprehensive treatment of real-time kinematic positioning using observations from the various satellite systems. Chapter 8 provides an excellent treatment on user antenna technology. This chapter is written by an antenna expert and is certainly of interest to geodesist and anyone concerned with accurate positioning.

Reading this book needs in-depth prior knowledge in this area. Dense argument is condensed in very deep ways, carry a great deal of freight. The content is very useful for insiders especially who are concerned about positioning solutions. The first errata sheet is already posted at www.onlineGNSS.com.

I bought the book for a class at MTU taught by one of the authors. It is the seminal, authoritative book on the topic.

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