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Civil Avionics Systems, Second Edition, is an updated and in-depth practical guide to integrated avionic systems as applied to civil aircraft and this new edition has been expanded to include the latest developments in modern avionics. It describes avionic systems and potential developments in the field to help educate students and practitioners in the process of designing, building and operating modern aircraft in the contemporary aviation system. Integration is a predominant theme of this book, as aircraft systems are becoming more integrated and complex, but so is the economic, political…mehr
- Geräte: PC
- eBook Hilfe
Civil Avionics Systems, Second Edition, is an updated and in-depth practical guide to integrated avionic systems as applied to civil aircraft and this new edition has been expanded to include the latest developments in modern avionics. It describes avionic systems and potential developments in the field to help educate students and practitioners in the process of designing, building and operating modern aircraft in the contemporary aviation system. Integration is a predominant theme of this book, as aircraft systems are becoming more integrated and complex, but so is the economic, political and technical environment in which they operate. Key features: * Content is based on many years of practical industrial experience by the authors on a range of civil and military projects * Generates an understanding of the integration and interconnectedness of systems in modern complex aircraft * Updated contents in the light of latest applications * Substantial new material has been included in the areas of avionics technology, software and system safety The authors are all recognised experts in the field and between them have over 140 years' experience in the aircraft industry. Their direct and accessible style ensures that Civil Avionics Systems, Second Edition is a must-have guide to integrated avionic systems in modern aircraft for those in the aerospace industry and academia.
Produktdetails
- Produktdetails
- Verlag: John Wiley & Sons
- Seitenzahl: 608
- Erscheinungstermin: 5. August 2013
- Englisch
- ISBN-13: 9781118536735
- Artikelnr.: 39478124
- Verlag: John Wiley & Sons
- Seitenzahl: 608
- Erscheinungstermin: 5. August 2013
- Englisch
- ISBN-13: 9781118536735
- Artikelnr.: 39478124
Ian Moir, Moir Associates, UK, After 20 years in the royal Air Force as an engineering officer, Ian went on to Smiths Industries in the UK where he was involved in a number of advanced projects. Since retiring from Smiths he is now in demand as a highly respected consultant. Ian has broad and detailed experience working in aircraft avionics systems in both military and civil aircraft. From the RAF Tornado and Apache helicopter to the Boeing 777, Ian's work has kept him at the forefront of new system developments and integrated systems in the areas of more-electric technology and systems implementations. He has a special interest in fostering training and education in aerospace engineering. Allan Seabridge, Seabridge Systems Ltd, UK, Allan Seabridge retired as Head of Flight Systems Engineering after a long career with BAE Systems. He has 36 years experience in aerospace systems engineering, business development and research & development, with major projects worked on including Canberra, Jaguar, Tornado, EAP, Typhoon & Nimrod. Since retiring he has developed an interest in engineering education leading to the design and delivery of systems and engineering courses at a number of UK universities at undergraduate and postgraduate level. He also provides technical consultancy to companies in the aerospace industry. Malcolm Jukes, UK, Malcolm Jukes has over 35 years experience in the aerospace industry, mostly working for the Smiths Group at Cheltenham, UK. Among his many responsibilities as Chief Engineer for Defence Systems Cheltenham, Malcolm managed the design and experimental flight trials of the first UK Electronic Flight Instrument System (EFIS). Malcolm is now an aerospace consultant operating in the areas of displays, display systems, and mission computing.
About the Authors xix Series Preface xxi Preface to Second Edition xxii
Preface to First Edition xxiii Acknowledgements xxv List of Abbreviations
xxvi 1 Introduction 1 1.1 Advances since 2003 1 1.2 Comparison of Boeing
and Airbus Solutions 2 1.3 Outline of Book Content 2 1.4 The Appendices 4 2
Avionics Technology 7 2.1 Introduction 7 2.2 Avionics Technology Evolution
8 2.3 Avionics Computing 11 2.4 Digital Systems Input and Output 19 2.5
Binary Arithmetic 29 2.6 The Central Processing Unit (CPU) 34 2.7 Software
43 2.8 Microprocessors 53 2.9 Memory Technologies 59 2.10
Application-Specific Integrated Circuits (ASICs) 64 2.11 Integrated
Circuits 70 2.12 Integrated Circuit Packaging 73 3 Data Bus Networks 79 3.1
Introduction 79 3.2 Digital Data Bus Basics 80 3.3 Transmission Protocols
84 3.4 ARINC 429 88 3.5 MIL-STD-1553B 91 3.6 ARINC 629 97 3.7 ARINC 664
Part 7 100 3.8 CANbus 110 3.9 Time Triggered Protocol 113 3.10 Fibre-optic
Data Communications 113 3.11 Data Bus Summary 115 4 System Safety 119 4.1
Introduction 119 4.2 Flight Safety 120 4.3 System Safety Assessment 124 4.4
Reliability 128 4.5 Availability 134 4.6 Integrity 138 4.7 Redundancy 141
4.8 Analysis Methods 148 4.9 Other Considerations 151 5 Avionics
Architectures 159 5.1 Introduction 159 5.2 Avionics Architecture Evolution
159 5.3 Avionic Systems Domains 169 5.4 Avionics Architecture Examples 172
5.5 IMA Design Principles 188 5.6 The Virtual System 189 5.7 Partitioning
194 5.8 IMA Fault Tolerance 195 5.9 Network Definition 197 5.10
Certification 198 5.11 IMA Standards 201 6 Systems Development 205 6.1
Introduction 205 6.2 System Design Guidelines 206 6.3 Interrelationship of
Design Processes 210 6.4 Requirements Capture and Analysis 213 6.5
Development Processes 217 6.6 Development Programme 224 6.7 Extended
Operations Requirements 226 6.8 ARINC Specifications and Design Rigour 229
6.9 Interface Control 231 7 Electrical Systems 235 7.1 Electrical Systems
Overview 235 7.2 Electrical Power Generation 239 7.3 Power Distribution and
Protection 248 7.4 Emergency Power 254 7.5 Power System Architectures 259
7.6 Aircraft Wiring 268 7.7 Electrical Installation 276 7.8 Bonding and
Earthing 280 7.9 Signal Conditioning 282 7.10 Central Maintenance Systems
284 8 Sensors 291 8.1 Introduction 291 8.2 Air Data Sensors 292 8.3
Magnetic Sensors 301 8.4 Inertial Sensors 306 8.5 Combined Air Data and
Inertial 317 8.6 Radar Sensors 323 9 Communications and Navigation Aids 329
9.1 Introduction 329 9.2 Communications 332 9.3 Ground-Based Navigation
Aids 347 9.4 Instrument Landing Systems 350 9.5 Space-Based Navigation
Systems 354 9.6 Communications Control Systems 362 10 Flight Control
Systems 365 10.1 Principles of Flight Control 365 10.2 Flight Control
Elements 368 10.3 Flight Control Actuation 371 10.4 Principles of
Fly-By-Wire 379 10.5 Boeing 777 Flight Control System 383 10.6 Airbus
Flight Control Systems 389 10.7 Autopilot Flight Director System 396 10.8
Flight Data Recorders 401 11 Navigation Systems 405 11.1 Principles of
Navigation 405 11.2 Flight Management System 413 11.3 Electronic Flight Bag
427 11.4 Air Traffic Management 430 11.5 Performance-Based Navigation 433
11.6 Automatic Dependent Surveillance - Broadcast 442 11.7 Boeing and
Airbus Implementations 442 11.8 Terrain Avoidance Warning System (TAWS) 444
12 Flight Deck Displays 449 12.1 Introduction 449 12.2 First Generation
Flight Deck: the Electromagnetic Era 450 12.3 Second Generation Flight
Deck: the Electro-Optic Era 455 12.4 Third Generation: the Next Generation
Flight Deck 463 12.5 Electronic Centralised Aircraft Monitor (ECAM) System
465 12.6 Standby Instruments 468 12.7 Head-Up Display Visual Guidance
System (HVGS) 469 12.8 Enhanced and Synthetic Vision Systems 473 12.9
Display System Architectures 486 12.9.1 Airworthiness Regulations 486
12.9.2 Display Availability and Integrity 486 12.9.3 Display System
Functional Elements 487 12.9.4 Dumb Display Architecture 488 12.9.5
Semi-Smart Display Architecture 490 12.9.6 Fully Smart (Integrated) Display
Architecture 490 12.10 Display Usability 491 12.11 Display Technologies 498
12.12 Flight Control Inceptors 506 13 Military Aircraft Adaptations 511
13.1 Introduction 511 13.2 Avionic and Mission System Interface 512 13.3
Applications 519 Reference 531 Further Reading 531 Appendices 533
Introduction to Appendices 533 Appendix A: Safety Analysis - Flight Control
System 534 A.1 Flight Control System Architecture 534 A.2 Dependency
Diagram 535 A.3 Fault Tree Analysis 537 Appendix B: Safety Analysis -
Electronic Flight Instrument System 539 B.1 Electronic Flight Instrument
System Architecture 539 B.2 Fault Tree Analysis 540 Appendix C: Safety
Analysis - Electrical System 543 C.1 Electrical System Architecture 543 C.2
Fault Tree Analysis 543 Appendix D: Safety Analysis - Engine Control System
546 D.1 Factors Resulting in an In-Flight Shut Down 546 D.2 Engine Control
System Architecture 546 D.3 Markov Analysis 548 Simplified Example (all
failure rates per flight hour) 549 Index 551
Preface to First Edition xxiii Acknowledgements xxv List of Abbreviations
xxvi 1 Introduction 1 1.1 Advances since 2003 1 1.2 Comparison of Boeing
and Airbus Solutions 2 1.3 Outline of Book Content 2 1.4 The Appendices 4 2
Avionics Technology 7 2.1 Introduction 7 2.2 Avionics Technology Evolution
8 2.3 Avionics Computing 11 2.4 Digital Systems Input and Output 19 2.5
Binary Arithmetic 29 2.6 The Central Processing Unit (CPU) 34 2.7 Software
43 2.8 Microprocessors 53 2.9 Memory Technologies 59 2.10
Application-Specific Integrated Circuits (ASICs) 64 2.11 Integrated
Circuits 70 2.12 Integrated Circuit Packaging 73 3 Data Bus Networks 79 3.1
Introduction 79 3.2 Digital Data Bus Basics 80 3.3 Transmission Protocols
84 3.4 ARINC 429 88 3.5 MIL-STD-1553B 91 3.6 ARINC 629 97 3.7 ARINC 664
Part 7 100 3.8 CANbus 110 3.9 Time Triggered Protocol 113 3.10 Fibre-optic
Data Communications 113 3.11 Data Bus Summary 115 4 System Safety 119 4.1
Introduction 119 4.2 Flight Safety 120 4.3 System Safety Assessment 124 4.4
Reliability 128 4.5 Availability 134 4.6 Integrity 138 4.7 Redundancy 141
4.8 Analysis Methods 148 4.9 Other Considerations 151 5 Avionics
Architectures 159 5.1 Introduction 159 5.2 Avionics Architecture Evolution
159 5.3 Avionic Systems Domains 169 5.4 Avionics Architecture Examples 172
5.5 IMA Design Principles 188 5.6 The Virtual System 189 5.7 Partitioning
194 5.8 IMA Fault Tolerance 195 5.9 Network Definition 197 5.10
Certification 198 5.11 IMA Standards 201 6 Systems Development 205 6.1
Introduction 205 6.2 System Design Guidelines 206 6.3 Interrelationship of
Design Processes 210 6.4 Requirements Capture and Analysis 213 6.5
Development Processes 217 6.6 Development Programme 224 6.7 Extended
Operations Requirements 226 6.8 ARINC Specifications and Design Rigour 229
6.9 Interface Control 231 7 Electrical Systems 235 7.1 Electrical Systems
Overview 235 7.2 Electrical Power Generation 239 7.3 Power Distribution and
Protection 248 7.4 Emergency Power 254 7.5 Power System Architectures 259
7.6 Aircraft Wiring 268 7.7 Electrical Installation 276 7.8 Bonding and
Earthing 280 7.9 Signal Conditioning 282 7.10 Central Maintenance Systems
284 8 Sensors 291 8.1 Introduction 291 8.2 Air Data Sensors 292 8.3
Magnetic Sensors 301 8.4 Inertial Sensors 306 8.5 Combined Air Data and
Inertial 317 8.6 Radar Sensors 323 9 Communications and Navigation Aids 329
9.1 Introduction 329 9.2 Communications 332 9.3 Ground-Based Navigation
Aids 347 9.4 Instrument Landing Systems 350 9.5 Space-Based Navigation
Systems 354 9.6 Communications Control Systems 362 10 Flight Control
Systems 365 10.1 Principles of Flight Control 365 10.2 Flight Control
Elements 368 10.3 Flight Control Actuation 371 10.4 Principles of
Fly-By-Wire 379 10.5 Boeing 777 Flight Control System 383 10.6 Airbus
Flight Control Systems 389 10.7 Autopilot Flight Director System 396 10.8
Flight Data Recorders 401 11 Navigation Systems 405 11.1 Principles of
Navigation 405 11.2 Flight Management System 413 11.3 Electronic Flight Bag
427 11.4 Air Traffic Management 430 11.5 Performance-Based Navigation 433
11.6 Automatic Dependent Surveillance - Broadcast 442 11.7 Boeing and
Airbus Implementations 442 11.8 Terrain Avoidance Warning System (TAWS) 444
12 Flight Deck Displays 449 12.1 Introduction 449 12.2 First Generation
Flight Deck: the Electromagnetic Era 450 12.3 Second Generation Flight
Deck: the Electro-Optic Era 455 12.4 Third Generation: the Next Generation
Flight Deck 463 12.5 Electronic Centralised Aircraft Monitor (ECAM) System
465 12.6 Standby Instruments 468 12.7 Head-Up Display Visual Guidance
System (HVGS) 469 12.8 Enhanced and Synthetic Vision Systems 473 12.9
Display System Architectures 486 12.9.1 Airworthiness Regulations 486
12.9.2 Display Availability and Integrity 486 12.9.3 Display System
Functional Elements 487 12.9.4 Dumb Display Architecture 488 12.9.5
Semi-Smart Display Architecture 490 12.9.6 Fully Smart (Integrated) Display
Architecture 490 12.10 Display Usability 491 12.11 Display Technologies 498
12.12 Flight Control Inceptors 506 13 Military Aircraft Adaptations 511
13.1 Introduction 511 13.2 Avionic and Mission System Interface 512 13.3
Applications 519 Reference 531 Further Reading 531 Appendices 533
Introduction to Appendices 533 Appendix A: Safety Analysis - Flight Control
System 534 A.1 Flight Control System Architecture 534 A.2 Dependency
Diagram 535 A.3 Fault Tree Analysis 537 Appendix B: Safety Analysis -
Electronic Flight Instrument System 539 B.1 Electronic Flight Instrument
System Architecture 539 B.2 Fault Tree Analysis 540 Appendix C: Safety
Analysis - Electrical System 543 C.1 Electrical System Architecture 543 C.2
Fault Tree Analysis 543 Appendix D: Safety Analysis - Engine Control System
546 D.1 Factors Resulting in an In-Flight Shut Down 546 D.2 Engine Control
System Architecture 546 D.3 Markov Analysis 548 Simplified Example (all
failure rates per flight hour) 549 Index 551
About the Authors xix Series Preface xxi Preface to Second Edition xxii
Preface to First Edition xxiii Acknowledgements xxv List of Abbreviations
xxvi 1 Introduction 1 1.1 Advances since 2003 1 1.2 Comparison of Boeing
and Airbus Solutions 2 1.3 Outline of Book Content 2 1.4 The Appendices 4 2
Avionics Technology 7 2.1 Introduction 7 2.2 Avionics Technology Evolution
8 2.3 Avionics Computing 11 2.4 Digital Systems Input and Output 19 2.5
Binary Arithmetic 29 2.6 The Central Processing Unit (CPU) 34 2.7 Software
43 2.8 Microprocessors 53 2.9 Memory Technologies 59 2.10
Application-Specific Integrated Circuits (ASICs) 64 2.11 Integrated
Circuits 70 2.12 Integrated Circuit Packaging 73 3 Data Bus Networks 79 3.1
Introduction 79 3.2 Digital Data Bus Basics 80 3.3 Transmission Protocols
84 3.4 ARINC 429 88 3.5 MIL-STD-1553B 91 3.6 ARINC 629 97 3.7 ARINC 664
Part 7 100 3.8 CANbus 110 3.9 Time Triggered Protocol 113 3.10 Fibre-optic
Data Communications 113 3.11 Data Bus Summary 115 4 System Safety 119 4.1
Introduction 119 4.2 Flight Safety 120 4.3 System Safety Assessment 124 4.4
Reliability 128 4.5 Availability 134 4.6 Integrity 138 4.7 Redundancy 141
4.8 Analysis Methods 148 4.9 Other Considerations 151 5 Avionics
Architectures 159 5.1 Introduction 159 5.2 Avionics Architecture Evolution
159 5.3 Avionic Systems Domains 169 5.4 Avionics Architecture Examples 172
5.5 IMA Design Principles 188 5.6 The Virtual System 189 5.7 Partitioning
194 5.8 IMA Fault Tolerance 195 5.9 Network Definition 197 5.10
Certification 198 5.11 IMA Standards 201 6 Systems Development 205 6.1
Introduction 205 6.2 System Design Guidelines 206 6.3 Interrelationship of
Design Processes 210 6.4 Requirements Capture and Analysis 213 6.5
Development Processes 217 6.6 Development Programme 224 6.7 Extended
Operations Requirements 226 6.8 ARINC Specifications and Design Rigour 229
6.9 Interface Control 231 7 Electrical Systems 235 7.1 Electrical Systems
Overview 235 7.2 Electrical Power Generation 239 7.3 Power Distribution and
Protection 248 7.4 Emergency Power 254 7.5 Power System Architectures 259
7.6 Aircraft Wiring 268 7.7 Electrical Installation 276 7.8 Bonding and
Earthing 280 7.9 Signal Conditioning 282 7.10 Central Maintenance Systems
284 8 Sensors 291 8.1 Introduction 291 8.2 Air Data Sensors 292 8.3
Magnetic Sensors 301 8.4 Inertial Sensors 306 8.5 Combined Air Data and
Inertial 317 8.6 Radar Sensors 323 9 Communications and Navigation Aids 329
9.1 Introduction 329 9.2 Communications 332 9.3 Ground-Based Navigation
Aids 347 9.4 Instrument Landing Systems 350 9.5 Space-Based Navigation
Systems 354 9.6 Communications Control Systems 362 10 Flight Control
Systems 365 10.1 Principles of Flight Control 365 10.2 Flight Control
Elements 368 10.3 Flight Control Actuation 371 10.4 Principles of
Fly-By-Wire 379 10.5 Boeing 777 Flight Control System 383 10.6 Airbus
Flight Control Systems 389 10.7 Autopilot Flight Director System 396 10.8
Flight Data Recorders 401 11 Navigation Systems 405 11.1 Principles of
Navigation 405 11.2 Flight Management System 413 11.3 Electronic Flight Bag
427 11.4 Air Traffic Management 430 11.5 Performance-Based Navigation 433
11.6 Automatic Dependent Surveillance - Broadcast 442 11.7 Boeing and
Airbus Implementations 442 11.8 Terrain Avoidance Warning System (TAWS) 444
12 Flight Deck Displays 449 12.1 Introduction 449 12.2 First Generation
Flight Deck: the Electromagnetic Era 450 12.3 Second Generation Flight
Deck: the Electro-Optic Era 455 12.4 Third Generation: the Next Generation
Flight Deck 463 12.5 Electronic Centralised Aircraft Monitor (ECAM) System
465 12.6 Standby Instruments 468 12.7 Head-Up Display Visual Guidance
System (HVGS) 469 12.8 Enhanced and Synthetic Vision Systems 473 12.9
Display System Architectures 486 12.9.1 Airworthiness Regulations 486
12.9.2 Display Availability and Integrity 486 12.9.3 Display System
Functional Elements 487 12.9.4 Dumb Display Architecture 488 12.9.5
Semi-Smart Display Architecture 490 12.9.6 Fully Smart (Integrated) Display
Architecture 490 12.10 Display Usability 491 12.11 Display Technologies 498
12.12 Flight Control Inceptors 506 13 Military Aircraft Adaptations 511
13.1 Introduction 511 13.2 Avionic and Mission System Interface 512 13.3
Applications 519 Reference 531 Further Reading 531 Appendices 533
Introduction to Appendices 533 Appendix A: Safety Analysis - Flight Control
System 534 A.1 Flight Control System Architecture 534 A.2 Dependency
Diagram 535 A.3 Fault Tree Analysis 537 Appendix B: Safety Analysis -
Electronic Flight Instrument System 539 B.1 Electronic Flight Instrument
System Architecture 539 B.2 Fault Tree Analysis 540 Appendix C: Safety
Analysis - Electrical System 543 C.1 Electrical System Architecture 543 C.2
Fault Tree Analysis 543 Appendix D: Safety Analysis - Engine Control System
546 D.1 Factors Resulting in an In-Flight Shut Down 546 D.2 Engine Control
System Architecture 546 D.3 Markov Analysis 548 Simplified Example (all
failure rates per flight hour) 549 Index 551
Preface to First Edition xxiii Acknowledgements xxv List of Abbreviations
xxvi 1 Introduction 1 1.1 Advances since 2003 1 1.2 Comparison of Boeing
and Airbus Solutions 2 1.3 Outline of Book Content 2 1.4 The Appendices 4 2
Avionics Technology 7 2.1 Introduction 7 2.2 Avionics Technology Evolution
8 2.3 Avionics Computing 11 2.4 Digital Systems Input and Output 19 2.5
Binary Arithmetic 29 2.6 The Central Processing Unit (CPU) 34 2.7 Software
43 2.8 Microprocessors 53 2.9 Memory Technologies 59 2.10
Application-Specific Integrated Circuits (ASICs) 64 2.11 Integrated
Circuits 70 2.12 Integrated Circuit Packaging 73 3 Data Bus Networks 79 3.1
Introduction 79 3.2 Digital Data Bus Basics 80 3.3 Transmission Protocols
84 3.4 ARINC 429 88 3.5 MIL-STD-1553B 91 3.6 ARINC 629 97 3.7 ARINC 664
Part 7 100 3.8 CANbus 110 3.9 Time Triggered Protocol 113 3.10 Fibre-optic
Data Communications 113 3.11 Data Bus Summary 115 4 System Safety 119 4.1
Introduction 119 4.2 Flight Safety 120 4.3 System Safety Assessment 124 4.4
Reliability 128 4.5 Availability 134 4.6 Integrity 138 4.7 Redundancy 141
4.8 Analysis Methods 148 4.9 Other Considerations 151 5 Avionics
Architectures 159 5.1 Introduction 159 5.2 Avionics Architecture Evolution
159 5.3 Avionic Systems Domains 169 5.4 Avionics Architecture Examples 172
5.5 IMA Design Principles 188 5.6 The Virtual System 189 5.7 Partitioning
194 5.8 IMA Fault Tolerance 195 5.9 Network Definition 197 5.10
Certification 198 5.11 IMA Standards 201 6 Systems Development 205 6.1
Introduction 205 6.2 System Design Guidelines 206 6.3 Interrelationship of
Design Processes 210 6.4 Requirements Capture and Analysis 213 6.5
Development Processes 217 6.6 Development Programme 224 6.7 Extended
Operations Requirements 226 6.8 ARINC Specifications and Design Rigour 229
6.9 Interface Control 231 7 Electrical Systems 235 7.1 Electrical Systems
Overview 235 7.2 Electrical Power Generation 239 7.3 Power Distribution and
Protection 248 7.4 Emergency Power 254 7.5 Power System Architectures 259
7.6 Aircraft Wiring 268 7.7 Electrical Installation 276 7.8 Bonding and
Earthing 280 7.9 Signal Conditioning 282 7.10 Central Maintenance Systems
284 8 Sensors 291 8.1 Introduction 291 8.2 Air Data Sensors 292 8.3
Magnetic Sensors 301 8.4 Inertial Sensors 306 8.5 Combined Air Data and
Inertial 317 8.6 Radar Sensors 323 9 Communications and Navigation Aids 329
9.1 Introduction 329 9.2 Communications 332 9.3 Ground-Based Navigation
Aids 347 9.4 Instrument Landing Systems 350 9.5 Space-Based Navigation
Systems 354 9.6 Communications Control Systems 362 10 Flight Control
Systems 365 10.1 Principles of Flight Control 365 10.2 Flight Control
Elements 368 10.3 Flight Control Actuation 371 10.4 Principles of
Fly-By-Wire 379 10.5 Boeing 777 Flight Control System 383 10.6 Airbus
Flight Control Systems 389 10.7 Autopilot Flight Director System 396 10.8
Flight Data Recorders 401 11 Navigation Systems 405 11.1 Principles of
Navigation 405 11.2 Flight Management System 413 11.3 Electronic Flight Bag
427 11.4 Air Traffic Management 430 11.5 Performance-Based Navigation 433
11.6 Automatic Dependent Surveillance - Broadcast 442 11.7 Boeing and
Airbus Implementations 442 11.8 Terrain Avoidance Warning System (TAWS) 444
12 Flight Deck Displays 449 12.1 Introduction 449 12.2 First Generation
Flight Deck: the Electromagnetic Era 450 12.3 Second Generation Flight
Deck: the Electro-Optic Era 455 12.4 Third Generation: the Next Generation
Flight Deck 463 12.5 Electronic Centralised Aircraft Monitor (ECAM) System
465 12.6 Standby Instruments 468 12.7 Head-Up Display Visual Guidance
System (HVGS) 469 12.8 Enhanced and Synthetic Vision Systems 473 12.9
Display System Architectures 486 12.9.1 Airworthiness Regulations 486
12.9.2 Display Availability and Integrity 486 12.9.3 Display System
Functional Elements 487 12.9.4 Dumb Display Architecture 488 12.9.5
Semi-Smart Display Architecture 490 12.9.6 Fully Smart (Integrated) Display
Architecture 490 12.10 Display Usability 491 12.11 Display Technologies 498
12.12 Flight Control Inceptors 506 13 Military Aircraft Adaptations 511
13.1 Introduction 511 13.2 Avionic and Mission System Interface 512 13.3
Applications 519 Reference 531 Further Reading 531 Appendices 533
Introduction to Appendices 533 Appendix A: Safety Analysis - Flight Control
System 534 A.1 Flight Control System Architecture 534 A.2 Dependency
Diagram 535 A.3 Fault Tree Analysis 537 Appendix B: Safety Analysis -
Electronic Flight Instrument System 539 B.1 Electronic Flight Instrument
System Architecture 539 B.2 Fault Tree Analysis 540 Appendix C: Safety
Analysis - Electrical System 543 C.1 Electrical System Architecture 543 C.2
Fault Tree Analysis 543 Appendix D: Safety Analysis - Engine Control System
546 D.1 Factors Resulting in an In-Flight Shut Down 546 D.2 Engine Control
System Architecture 546 D.3 Markov Analysis 548 Simplified Example (all
failure rates per flight hour) 549 Index 551