System Health Management
John Wiley & Sons Inc (Verlag)
978-0-470-74133-7 (ISBN)
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System Health Management: with Aerospace Applications provides the first complete reference text for System Health Management (SHM), the set of technologies and processes used to improve system dependability. Edited by a team of engineers and consultants with SHM design, development, and research experience from NASA, industry, and academia, each heading up sections in their own areas of expertise and co-coordinating contributions from leading experts, the book collates together in one text the state-of-the-art in SHM research, technology, and applications. It has been written primarily as a reference text for practitioners, for those in related disciplines, and for graduate students in aerospace or systems engineering. There are many technologies involved in SHM and no single person can be an expert in all aspects of the discipline.System Health Management: with Aerospace Applications provides an introduction to the major technologies, issues, and references in these disparate but related SHM areas. Since SHM has evolved most rapidly in aerospace, the various applications described in this book are taken primarily from the aerospace industry. However, the theories, techniques, and technologies discussed are applicable to many engineering disciplines and application areas.
Readers will find sections on the basic theories and concepts of SHM, how it is applied in the system life cycle (architecture, design, verification and validation, etc.), the most important methods used (reliability, quality assurance, diagnostics, prognostics, etc.), and how SHM is applied in operations (commercial aircraft, launch operations, logistics, etc.), to subsystems (electrical power, structures, flight controls, etc.) and to system applications (robotic spacecraft, tactical missiles, rotorcraft, etc.).
Dr Stephen B. Johnson is a Heath Management Systems Engineer at the NASA Marshall Space Flight Center in the USA, as well as an associate research professor at the University of Colorado at Colorado Springs. He has been active in the field of SHM for over 20 years, and has authored many research papers on the topic. He has also authored or edited 3 books in the aerospace field including The Secret of Apollo: Systems Management in American and European Space Programs. Mr Thomas Gormley has been involved with the NASA Aerospace industry for over 20 years, and was the Integrated Vehicle Health Management Project Leader for Rockwell Space Systems during the early 1990s. He brings expertise in systems implementation to the project. Dr Seth S. Kessler is president and owner of Metis Design Corporation, a design consulting firm specializing in custom sensing solutions. He brings expertise in structural health monitoring and composite materials to the project. Mr Charles Mott is a business analyst with the Tauri group, currently under contract at NASA. He brings expertise in the socio-technical aspects of large-scale technological projects to the project. Dr Ann Patterson-Hine is Group Leader of the Health Management Technologies Group at the Ames Research Center. She brings expertise on the use of engineering models for model-based reasoning in advanced monitoring and diagnostic systems to the project. Dr Karl Reichard is head of the ARL Penn State Monitoring and Automation Department. He brings expertise in the implementation of signal processing, control and embedded diagnost Mr Philip A. Scandura, Jr joined Honeywell in 1984 where he currently holds the position of Staff Scientist in their Advanced Technology Organization. He brings expertise in the system definition and implementation of real-time, embedded systems for use in safety-critical and mission-critical applications to the project.
About the Editors xxiii List of Contributors xxv
Foreword xxix
Preface xxxiii
Part One THE SOCIO-TECHNICAL CONTEXT OF SYSTEM HEALTH MANAGEMENT
Charles D. Mott
1 The Theory of System Health Management 3
Stephen B. Johnson
Overview 3
1.1 Introduction 3
1.2 Functions, Off-Nominal States, and Causation 7
1.3 Complexity and Knowledge Limitations 10
1.4 SHM Mitigation Strategies 11
1.5 Operational Fault Management Functions 12
1.6 Mechanisms 19
1.7 Summary of Principles 22
1.8 SHM Implementation 23
1.9 Some Implications 24
1.10 Conclusion 26
Bibliography 26
2 Multimodal Communication 29
Beverly A. Sauer
Overview 29
2.1 Multimodal Communication in SHM 31
2.2 Communication Channels 34
2.3 Learning from Disaster 36
2.4 Current Communication in the Aerospace Industry 37
2.5 The Problem of Sense-making in SHM Communication 37
2.6 The Costs of Faulty Communication 38
2.7 Implications 39
2.8 Conclusion 41
Acknowledgments 43
Bibliography 43
3 Highly Reliable Organizations 49
Andrew Wiedlea
Overview 49
3.1 The Study of HROs and Design for Dependability 49
3.2 Lessons from the Field: HRO Patterns of Behavior 52
3.2.1 Inseparability of Systemic Equipment and Anthropologic Hazards 53
3.2.2 Dynamic Management of System Risks 54
3.2.3 Social Perceptions of Benefits and Hazards 56
3.3 Dependable Design, Organizational Behavior, and Connections to the HRO Project 57
3.4 Conclusion 60
Bibliography 61
4 Knowledge Management 65
Edward W. Rogers
Overview 65
4.1 Systems as Embedded Knowledge 66
4.2 KM and Information Technology 66
4.3 Reliability and Sustainability of Organizational Systems 67
4.4 Case Study of Building a Learning Organization: Goddard Space Flight Center 69
4.5 Conclusion 75
Bibliography 75
5 The Business Case for SHM 77
Kirby Keller and James Poblete
Overview 77
5.1 Business Case Processes and Tools 78
5.2 Metrics to Support the Decision Process 80
5.3 Factors to Consider in Developing an Enterprise Model 82
5.4 Evaluation of Alternatives 86
5.5 Modifications in Selected Baseline Model 86
5.6 Modeling Risk and Uncertainty 87
5.7 Model Verification and Validation 88
5.8 Evaluation Results 88
5.9 Conclusion 90
Bibliography 91
Part Two SHM AND THE SYSTEM LIFECYCLE
Seth S. Kessler
6 Health Management Systems Engineering and Integration 95
Timothy J. Wilmering and Charles D. Mott
Overview 95
6.1 Introduction 95
6.2 Systems Thinking 96
6.3 Knowledge Management 97
6.4 Systems Engineering 98
6.5 Systems Engineering Lifecycle Stages 99
6.6 Systems Engineering, Dependability, and Health Management 100
6.7 SHM Lifecycle Stages 103
6.8 SHM Analysis Models and Tools 110
6.9 Conclusion 112
Acknowledgments 112
Bibliography 112
7 Architecture 115
Ryan W. Deal and Seth S. Kessler
Overview 115
7.1 Introduction 115
7.2 SHM System Architecture Components 117
7.3 Examples of Power and Data Considerations 119
7.4 SHM System Architecture Characteristics 120
7.5 SHM System Architecture Advanced Concepts 126
7.6 Conclusion 126
Bibliography 127
8 System Design and Analysis Methods 129
Irem Y. Tumer
Overview 129
8.1 Introduction 129
8.2 Lifecycle Considerations 130
8.3 Design Methods and Practices for Effective SHM 132
8.4 Conclusion 141
Acknowledgments 142
Bibliography 142
9 Assessing and Maturing Technology Readiness Levels 145
Ryan M. Mackey
Overview 145
9.1 Introduction 145
9.2 Motivating Maturity Assessment 146
9.3 Review of Technology Readiness Levels 147
9.4 Special Needs of SHM 149
9.5 Mitigation Approaches 151
9.6 TRLs for SHM 153
9.7 A Sample Maturation Effort 154
9.8 Conclusion 156
Bibliography 157
10 Verification and Validation 159
Lawrence Z. Markosian, Martin S. Feather and David E. Brinza
Overview 159
10.1 Introduction 159
10.2 Existing Software V&V 160
10.3 Feasibility and Sufficiency of Existing Software V&V Practices for SHM 165
10.4 Opportunities for Emerging V&V Techniques Suited to SHM 167
10.5 V&V Considerations for SHM Sensors and Avionics 170
10.6 V&V Planning for a Specific SHM Application 171
10.7 A Systems Engineering Perspective on V&V of SHM 180
10.8 Conclusion 181
Acknowledgments 181
Bibliography 181
11 Certifying Vehicle Health Monitoring Systems 185
Seth S. Kessler, Thomas Brotherton and Grant A. Gordon
Overview 185
11.1 Introduction 185
11.2 Durability for VHM Systems 186
11.3 Mechanical Design for Structural Health Monitoring Systems 189
11.4 Reliability and Longevity of VHM Systems 190
11.5 Software and Hardware Certification 190
11.6 Airworthiness Certification 191
11.7 Health and Usage Monitoring System Certification Example 191
11.8 Conclusion 194
Acknowledgments 194
Bibliography 194
Part Three ANALYTICAL METHODS
Ann Patterson-Hine
12 Physics of Failure 199
Kumar V. Jata and Triplicane A. Parthasarathy
Overview 199
12.1 Introduction 200
12.2 Physics of Failure of Metals 201
12.3 Physics of Failure of CMCs 212
12.4 Conclusion 216
Bibliography 216
13 Failure Assessment 219
Robyn Lutz and Allen Nikora
Overview 219
13.1 Introduction 219
13.2 FMEA 220
13.3 SFMEA 221
13.4 FTA 222
13.5 SFTA 222
13.6 BDSA 223
13.7 Safety Analysis 225
13.8 Software Reliability Engineering 225
13.9 Tools and Automation 228
13.10 Future Directions 229
13.11 Conclusion 229
Acknowledgments 230
Bibliography 230
14 Reliability 233
William Q. Meeker and Luis A. Escobar
Overview 233
14.1 Time-to-Failure Model Concepts and Two Useful Distributions 233
14.2 Introduction to System Reliability 236
14.3 Analysis of Censored Life Data 239
14.4 Accelerated Life Testing 243
14.5 Analysis of Degradation Data 244
14.6 Analysis of Recurrence Data 246
14.7 Software for Statistical Analysis of Reliability Data 249
Acknowledgments 250
Bibliography 250
15 Probabilistic Risk Assessment 253
William E. Vesely
Overview 253
15.1 Introduction 253
15.2 The Space Shuttle PRA 254
15.3 Assessing Cumulative Risks to Assist Project Risk Management 254
15.4 Quantification of Software Reliability 257
15.5 Description of the Techniques Used in the Space Shuttle PRA 260
15.6 Conclusion 263
Bibliography 263
16 Diagnosis 265
Ann Patterson-Hine, Gordon B. Aaseng, Gautam Biswas, Sriram Narashimhan and Krishna Pattipati
Overview 265
16.1 Introduction 266
16.2 General Diagnosis Problem 267
16.3 Failure Effect Propagation and Impact 267
16.4 Testability Analysis 268
16.5 Diagnosis Techniques 268
16.6 Automation Considerations for Diagnostic Systems 276
16.7 Conclusion 277
Acknowledgments 277
Bibliography 277
17 Prognostics 281
Michael J. Roemer, Carl S. Byington, Gregory J. Kacprzynski, George Vachtsevanos and Kai Goebel
Overview 281
17.1 Background 282
17.2 Prognostic Algorithm Approaches 282
17.3 Prognosis RUL Probability Density Function 287
17.4 Adaptive Prognosis 287
17.5 Performance Metrics 289
17.6 Distributed Prognosis System Architecture 292
17.7 Conclusion 292
Bibliography 293
Part Four OPERATIONS
Karl M. Reichard
18 Quality Assurance 299
Brian K. Hughitt
Overview 299
18.1 NASA QA Policy Requirements 300
18.2 Quality System Criteria 302
18.3 Quality Clauses 303
18.4 Workmanship Standards 304
18.5 Government Contract Quality Assurance 304
18.6 Government Mandatory Inspection Points 305
18.7 Quality System Audit 306
18.8 Conclusion 307
Bibliography 308
19 Maintainability: Theory and Practice 309
Gary O’Neill
Overview 309
19.1 Definitions of Reliability and Maintainability 310
19.2 Reliability and Maintainability Engineering 311
19.3 The Practice of Maintainability 314
19.4 Improving R&M Measures 315
19.5 Conclusion 316
Bibliography 317
20 Human Factors 319
Robert S. McCann and Lilly Spirkovska
Overview 319
20.1 Background 320
20.2 Fault Management on Next-Generation Spacecraft 323
20.3 Integrated Fault Management Automation Today 325
20.4 Human–Automation Teaming for Real-Time FM 328
20.5 Operations Concepts for Crew–Automation Teaming 330
20.6 Empirical Testing and Evaluation 333
20.7 Future Steps 334
20.8 Conclusion 336
Bibliography 336
21 Launch Operations 339
Robert D. Waterman, Patricia E. Nicoli, Alan J. Zide, Susan J. Waterman, Jose M. Perotti, Robert A. Ferrell and Barbara L. Brown
Overview 339
21.1 Introduction to Launch Site Operations 339
21.2 Human-Centered Health Management 340
21.3 SHM 346
21.4 LS Abort and Emergency Egress 347
21.5 Future Trends Post Space Shuttle 348
21.6 Conclusion 349
Bibliography 349
22 Fault Management Techniques in Human Spaceflight Operations 351
Brian O’Hagan and Alan Crocker
Overview 351
22.1 The Flight Operations Team 352
22.2 System Architecture Implications 353
22.3 Operations Products, Processes and Techniques 358
22.4 Lessons Learned from Space Shuttle and ISS Experience 364
22.5 Conclusion 366
Bibliography 367
23 Military Logistics 369
Eddie C. Crow and Karl M. Reichard
Overview 369
23.1 Focused Logistics 371
23.2 USMC AL 373
23.3 Benefits and Impact of SHM on Military Operations and Logistics 378
23.4 Demonstrating the Value of SHM in Military Operations and Logistics 381
23.5 Conclusion 385
Bibliography 386
Part Five SUBSYSTEM HEALTH MANAGEMENT
Philip A. Scandura, Jr.
24 Aircraft Propulsion Health Management 389
Al Volponi and Bruce Wood
Overview 389
24.1 Introduction 389
24.2 Basic Principles 390
24.3 Engine-Hosted Health Management 393
24.4 Operating Conditions 394
24.5 Computing Host 395
24.6 Software 396
24.7 On-Board Models 398
24.8 Component Life Usage Estimation 398
24.9 Design of an Engine Health Management System 399
24.10 Supporting a Layered Approach 401
24.11 Conclusion 401
Bibliography 402
25 Intelligent Sensors for Health Management 405
Gary W. Hunter, Lawrence G. Oberle, George Y. Baaklini, Jose M. Perotti and Todd Hong
Overview 405
25.1 Introduction 406
25.2 Sensor Technology Approaches 407
25.3 Sensor System Development 409
25.4 Supporting Technologies: High-Temperature Applications Example 412
25.5 Test Instrumentation and Non-destructive Evaluation (NDE) 413
25.6 Transition of Sensor Systems to Flight 414
25.7 Supporting a Layered Approach 415
25.8 Conclusion 416
Acknowledgments 417
Bibliography 417
26 Structural Health Monitoring 419
Fu-Kuo Chang, Johannes F.C. Markmiller, Jinkyu Yang and Yujun Kim
Overview 419
26.1 Introduction 419
26.2 Proposed Framework 421
26.3 Supporting a Layered Approach 427
26.4 Conclusion 427
Acknowledgments 427
Bibliography 427
27 Electrical Power Health Management 429
Robert M. Button and Amy Chicatelli
Overview 429
27.1 Introduction 429
27.2 Summary of Major EPS Components and their Failure Modes 431
27.3 Review of Current Power System HM 437
27.4 Future Power SHM 440
27.5 Supporting a Layered Approach 441
27.6 Conclusion 442
Bibliography 442
28 Avionics Health Management 445
Michael D. Watson, Kosta Varnavas, Clint Patrick, Ron Hodge, Carl S. Byington, Savio Chau and Edmund C. Baroth
Overview 445
28.1 Avionics Description 445
28.2 Electrical, Electronic and Electromechanical (EEE) Parts Qualification 448
28.3 Environments 450
28.4 Failure Sources 453
28.5 Current Avionics Health Management Techniques 453
28.6 Avionics Health Management Requirements 460
28.7 Supporting a Layered Approach 464
28.8 Conclusion 464
Bibliography 464
29 Failure-Tolerant Architectures for Health Management 467
Daniel P. Siewiorek and Priya Narasimhan
Overview 467
29.1 Introduction 467
29.2 System Failure Response Stages 468
29.3 System-Level Approaches to Reliability 469
29.4 Failure-Tolerant Software Architectures for Space Missions 470
29.5 Failure-Tolerant Software Architectures for Commercial Aviation Systems 475
29.6 Observations and Trends 477
29.7 Supporting a Layered Approach 480
29.8 Conclusion 480
Acknowledgments 481
Bibliography 481
30 Flight Control Health Management 483
Douglas J. Zimpfer
Overview 483
30.1 A FC Perspective on System Health Management 483
30.2 Elements of the FC System 485
30.3 FC Sensor and Actuator HM 485
30.4 FC/Flight Dynamics HM 490
30.5 FC HM Benefits 493
30.6 Supporting a Layered Approach 493
30.7 Conclusion 493
Bibliography 494
31 Life Support Health Management 497
David Kortenkamp, Gautam Biswas and Eric-Jan Manders
Overview 497
31.1 Introduction 497
31.2 Modeling 501
31.3 System Architecture 504
31.4 Future NASA Life Support Applications 509
31.5 Supporting a Layered Approach 510
31.6 Conclusion 510
Bibliography 510
32 Software 513
Philip A. Scandura, Jr.
Overview 513
32.1 Sampling of Accidents Attributed to Software Failures 513
32.2 Current Practice 514
32.3 Challenges 517
32.4 Supporting a Layered Approach 518
32.5 Conclusion 518
Bibliography 518
Part Six SYSTEM APPLICATIONS
Thomas J. Gormley
33 Launch Vehicle Health Management 523
Edward N. Brown, Anthony R. Kelley and Thomas J. Gormley
Overview 523
33.1 Introduction 523
33.2 LVSHM Functionality and Scope 524
33.3 LV Terminology and Operations 526
33.4 LV Reliability Lessons Learned 527
33.5 LV Segment Requirements and Architecture 528
33.6 LVSHM Analysis and Design 529
33.7 LV LVSHM System Descriptions 534
33.8 LVSHM Future System Requirements 537
33.9 Conclusion 540
Bibliography 541
34 Robotic Spacecraft Health Management 543
Paula S. Morgan
Overview 543
34.1 Introduction 544
34.2 Spacecraft Health and Integrity Concerns for Deep-Space Missions 544
34.3 Spacecraft SHM Implementation Approaches 546
34.4 Standard FP Implementation 546
34.5 Robotic Spacecraft SHM Allocations 547
34.6 Spacecraft SHM Ground Rules and Requirements 548
34.7 SFP and SIFP Architectures 550
34.8 Conclusion 554
Bibliography 554
35 Tactical Missile Health Management 555
Abdul J. Kudiya and Stephen A. Marotta
Overview 555
35.1 Introduction 555
35.2 Stockpile Surveillance Findings 556
35.3 Probabilistic Prognostics Modeling 557
35.4 Conclusion 563
Bibliography 564
36 Strategic Missile Health Management 565
Gregory A. Ruderman
Overview 565
36.1 Introduction 565
36.2 Fundamentals of Solid Rocket Motors 566
36.3 Motor Components 567
36.4 Challenges for Strategic Rocket Health Management 568
36.5 State of the Art for Solid Rocket System Health Management (SHM) 570
36.6 Current Challenges Facing SRM SHM 572
36.7 Conclusion 574
Bibliography 574
37 Rotorcraft Health Management 577
Paula J. Dempsey and James J. Zakrajsek
Overview 577
37.1 Introduction 577
37.2 Rotorcraft System Health Management Standard Practices 579
37.3 New Practices 582
37.4 Lessons Learned 583
37.5 Future Challenges 584
37.6 Conclusion 585
Bibliography 585
38 Commercial Aviation Health Management 589
Philip A. Scandura, Jr., Michael Christensen, Daniel Lutz and Gary Bird
Overview 589
38.1 Commercial Aviation Challenge 590
38.2 Layered Approach to SHM 590
38.3 Evolution of Commercial Aviation SHM 591
38.4 Commercial State of the Art 593
38.5 The Next Generation: Intelligent Vehicles/Sense and Respond 600
38.6 Conclusion 603
Bibliography 603
Glossary 605
Acronyms 607
Index 617
Erscheint lt. Verlag | 25.7.2011 |
---|---|
Reihe/Serie | Aerospace Series (PEP) |
Verlagsort | New York |
Sprache | englisch |
Maße | 173 x 252 mm |
Gewicht | 1279 g |
Themenwelt | Geisteswissenschaften ► Psychologie ► Klinische Psychologie |
Geisteswissenschaften ► Psychologie ► Test in der Psychologie | |
Technik ► Elektrotechnik / Energietechnik | |
Technik ► Maschinenbau | |
ISBN-10 | 0-470-74133-3 / 0470741333 |
ISBN-13 | 978-0-470-74133-7 / 9780470741337 |
Zustand | Neuware |
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