Operations Research for Unmanned Systems (eBook, ePUB)
Redaktion: Cares, Jeffrey R.; Dickmann, John Q.
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Operations Research for Unmanned Systems (eBook, ePUB)
Redaktion: Cares, Jeffrey R.; Dickmann, John Q.
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The first edited volume addressing analysis for unmanned vehicles, with focus on operations research rather than engineering * The editors have a unique combination of extensive operational experience and technical expertise * Chapters address a wide-ranging set of examples, domains and applications * Accessible to a general readership and also informative for experts
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The first edited volume addressing analysis for unmanned vehicles, with focus on operations research rather than engineering * The editors have a unique combination of extensive operational experience and technical expertise * Chapters address a wide-ranging set of examples, domains and applications * Accessible to a general readership and also informative for experts
Dieser Download kann aus rechtlichen Gründen nur mit Rechnungsadresse in A, B, BG, CY, CZ, D, DK, EW, E, FIN, F, GR, HR, H, IRL, I, LT, L, LR, M, NL, PL, P, R, S, SLO, SK ausgeliefert werden.
Produktdetails
- Produktdetails
- Verlag: John Wiley & Sons
- Seitenzahl: 328
- Erscheinungstermin: 4. März 2016
- Englisch
- ISBN-13: 9781118918920
- Artikelnr.: 44870730
- Verlag: John Wiley & Sons
- Seitenzahl: 328
- Erscheinungstermin: 4. März 2016
- Englisch
- ISBN-13: 9781118918920
- Artikelnr.: 44870730
- Herstellerkennzeichnung Die Herstellerinformationen sind derzeit nicht verfügbar.
Jeffrey Cares is an author, entrepreneur and thought-leader in military innovation. He consults to the most senior levels of the international defense industry and is a leading researcher in collective robotics and networked warfare. He lectures internationally at senior service colleges on the future of combat, and he develops and conducts military and business war games. Harvard Business Review selected Jeff's research to the Top 20 list of "Breakthrough Ideas for 2006," and he has been featured in such Information Age bellwethers as Wired and Fast Company. A combat veteran of the first Gulf War, Jeff's military career included multiple command tours, over a decade of service on four-star staffs, service in the Pentagon and all Fleet Headquarters, and joint and combined operations worldwide. He is a retired Navy Captain. John Dickmann, Jr is a retired U.S. Navy submarine officer. A graduate of the U.S. Naval Academy, he served on active duty for 22 years in both attack and ballistic missile submarines, with shore assignments in both technical and policy organizations. Following his Navy career, he attended the Massachusetts Institute of Technology, earning a Ph.D. in Engineering Systems. His research focuses on architectures of complex socio-technical systems, emphasizing operational flexibility. He has conducted studies and analysis for the Naval Sea Systems Command, DARPA, the Office of the Secretary of Defense and numerous commercial customers.
About the contributors xiii Acknowledgements xix 1 Introduction 1 1.1 Introduction 1 1.2 Background and Scope 3 1.3 About the Chapters 4 References 6 2 The In
Transit Vigilant Covering Tour Problem for Routing Unmanned Ground Vehicles 7 2.1 Introduction 7 2.2 Background 8 2.3 CTP for UGV Coverage 9 2.4 The In
Transit Vigilant Covering Tour Problem 9 2.5 Mathematical Formulation 11 2.6 Extensions to Multiple Vehicles 14 2.7 Empirical Study 15 2.8 Analysis of Results 21 2.9 Other Extensions 24 2.10 Conclusions 25 Author Statement 25 References 25 3 Near
Optimal Assignment of UAVs to Targets Using a Market
Based Approach 27 3.1 Introduction 27 3.2 Problem Formulation 29 3.2.1 Inputs 29 3.2.2 Various Objective Functions 29 3.2.3 Outputs 31 3.3 Literature 31 3.3.1 Solutions to the MDVRP Variants 31 3.3.2 Market
Based Techniques 33 3.4 The Market
Based Solution 34 3.4.1 The Basic Market Solution 36 3.4.2 The Hierarchical Market 37 3.4.2.1 Motivation and Rationale 37 3.4.2.2 Algorithm Details 40 3.4.3 Adaptations for the Max
Pro Case 41 3.4.4 Summary 41 3.5 Results 42 3.5.1 Optimizing for Fuel
Consumption (Min
Sum) 43 3.5.2 Optimizing for Time (Min
Max) 44 3.5.3 Optimizing for Prioritized Targets (Max
Pro) 47 3.6 Recommendations for Implementation 51 3.7 Conclusions 52 Appendix 3.A A Mixed Integer Linear Programming (MILP) Formulation 53 3.A.1 Sub-tour Elimination Constraints 54 References 55 4 Considering Mine Countermeasures Exploratory Operations Conducted by Autonomous Underwater Vehicles 59 4.1 Background 59 4.2 Assumptions 61 4.3 Measures of Performance 62 4.4 Preliminary Results 64 4.5 Concepts of Operations 64 4.5.1 Gaps in Coverage 64 4.5.2 Aspect Angle Degradation 64 4.6 Optimality with Two Different Angular Observations 65 4.7 Optimality with N Different Angular Observations 66 4.8 Modeling and Algorithms 67 4.8.1 Monte Carlo Simulation 67 4.8.2 Deterministic Model 67 4.9 Random Search Formula Adapted to AUVs 68 4.10 Mine Countermeasures Exploratory Operations 70 4.11 Numerical Results 71 4.12 Non
uniform Mine Density Distributions 72 4.13 Conclusion 74 Appendix 4.A Optimal Observation Angle between Two AUV Legs 75 Appendix 4.B Probabilities of Detection 78 References 79 5 Optical Search by Unmanned Aerial Vehicles: Fauna Detection Case Study 81 5.1 Introduction 81 5.2 Search Planning for Unmanned Sensing Operations 82 5.2.1 Preliminary Flight Analysis 84 5.2.2 Flight Geometry Control 85 5.2.3 Images and Mosaics 86 5.2.4 Digital Analysis and Identification of Elements 88 5.3 Results 91 5.4 Conclusions 92 Acknowledgments 94 References 94 6 A Flight Time Approximation Model for Unmanned Aerial Vehicles: Estimating the Effects of Path Variations and Wind 95 Nomenclature 95 6.1 Introduction 96 6.2 Problem Statement 97 6.3 Literature Review 97 6.3.1 Flight Time Approximation Models 97 6.3.2 Additional Task Types to Consider 98 6.3.3 Wind Effects 99 6.4 Flight Time Approximation Model Development 99 6.4.1 Required Mathematical Calculations 100 6.4.2 Model Comparisons 101 6.4.3 Encountered Problems and Solutions 102 6.5 Additional Task Types 103 6.5.1 Radius of Sight Task 103 6.5.2 Loitering Task 105 6.6 Adding Wind Effects 108 6.6.1 Implementing the Fuel Burn Rate Model 110 6.7 Computational Expense of the Final Model 111 6.7.1 Model Runtime Analysis 111 6.7.2 Actual versus Expected Flight Times 113 6.8 Conclusions and Future Work 115 Acknowledgments 117 References 117 7 Impacts of Unmanned Ground Vehicles on Combined Arms Team Performance 119 7.1 Introduction 119 7.2 Study Problem 120 7.2.1 Terrain 120 7.2.2 Vehicle Options 122 7.2.3 Forces 122 7.2.3.1 Experimental Force 123 7.2.3.2 Opposition Force 123 7.2.3.3 Civilian Elements 123 7.2.4 Mission 124 7.3 Study Methods 125 7.3.1 Closed
Loop Simulation 125 7.3.2 Study Measures 126 7.3.3 System Comparison Approach 128 7.4 Study Results 128 7.4.1 Basic Casualty Results 128 7.4.1.1 Low Density Urban Terrain Casualty Only Results 128 7.4.1.2 Dense Urban Terrain Casualty
Only Results 130 7.4.2 Complete Measures Results 131 7.4.2.1 Low Density Urban Terrain Results 131 7.4.2.2 Dense Urban Terrain Results 132 7.4.2.3 Comparison of Low and High Density Urban Results 133 7.4.3 Casualty versus Full Measures Comparison 135 7.5 Discussion 136 References 137 8 Processing, Exploitation and Dissemination: When is Aided/Automated Target Recognition "Good Enough" for Operational Use? 139 8.1 Introduction 139 8.2 Background 140 8.2.1 Operational Context and Technical Issues 140 8.2.2 Previous Investigations 141 8.3 Analysis 143 8.3.1 Modeling the Mission 144 8.3.2 Modeling the Specific Concept of Operations 145 8.3.3 Probability of Acquiring the Target under the Concept of Operations 146 8.3.4 Rational Selection between Aided/Automated Target Recognition and Extended Human Sensing 147 8.3.5 Finding the Threshold at which Automation is Rational 148 8.3.6 Example 148 8.4 Conclusion 149 Acknowledgments 151 Appendix 8.A 151 Ensuring
[Q ] * decreases as
* increases 152 References 152 9 Analyzing a Design Continuum for Automated Military Convoy Operations 155 9.1 Introduction 155 9.2 Definition Development 156 9.2.1 Human Input Proportion (H) 156 9.2.2 Interaction Frequency 157 9.2.3 Complexity of Instructions/Tasks 157 9.2.4 Robotic Decision
Making Ability (R) 157 9.3 Automation Continuum 157 9.3.1 Status Quo (SQ) 158 9.3.2 Remote Control (RC) 158 9.3.3 Tele
Operation (TO) 158 9.3.4 Driver Warning (DW) 158 9.3.5 Driver Assist (DA) 158 9.3.6 Leader
Follower (LF) 159 9.3.6.1 Tethered Leader
Follower (LF1) 159 9.3.6.2 Un
tethered Leader
Follower (LF2) 159 9.3.6.3 Un
tethered/Unmanned/Pre
driven Leader
Follower (LF3) 159 9.3.6.4 Un
tethered/Unmanned/Uploaded Leader
Follower (LF4) 159 9.3.7 Waypoint (WA) 159 9.3.7.1 Pre
recorded "Breadcrumb" Waypoint (WA1) 160 9.3.7.2 Uploaded "Breadcrumb" Waypoint (WA2) 160 9.3.8 Full Automation (FA) 160 9.3.8.1 Uploaded "Breadcrumbs" with Route Suggestion Full Automation (FA1) 160 9.3.8.2 Self
Determining Full Automation (FA2) 160 9.4 Mathematically Modeling Human Input Proportion (H) versus System Configuration 161 9.4.1 Modeling H versus System Configuration Methodology 161 9.4.2 Analyzing the Results of Modeling H versus System Configuration 165 9.4.3 Partitioning the Automation Continuum for H versus System Configuration into Regimes and Analyzing the Results 168 9.5 Mathematically Modeling Robotic Decision
Making Ability (R) versus System Configuration 169 9.5.1 Modeling R versus System Configuration Methodology 169 9.5.2 Mathematically Modeling R versus System Configuration When Weighted by H 171 9.5.3 Partitioning the Automation Continuum for R (Weighted by H) versus System Configuration into Regimes 175 9.5.4 Summarizing the Results of Modeling H versus System Configuration and R versus System Configuration When Weighted by H 177 9.6 Mathematically Modeling H and R 178 9.6.1 Analyzing the Results of Modeling H versus R 178 9.7 Conclusion 180 9.A System Configurations 180 10 Experimental Design for Unmanned Aerial Systems Analysis: Bringing Statistical Rigor to UAS Testing 187 10.1 Introduction 187 10.2 Some UAS History 188 10.3 Statistical Background for Experimental Planning 189 10.4 Planning the UAS Experiment 192 10.4.1 General Planning Guidelines 192 10.4.2 Planning Guidelines for UAS Testing 193 10.4.2.1 Determine Specific Questions to Answer 194 10.4.2.2 Determine Role of the Human Operator 194 10.4.2.3 Define and Delineate Factors of Concern for the Study 195 10.4.2.4 Determine and Correlate Response Data 196 10.4.2.5 Select an Appropriate Design 196 10.4.2.6 Define the Test Execution Strategy 198 10.5 Applications of the UAS Planning Guidelines 199 10.5.1 Determine the Specific Research Questions 199 10.5.2 Determining the Role of Human Operators 199 10.5.3 Determine the Response Data 200 10.5.4 Define the Experimental Factors 200 10.5.5 Establishing the Experimental Protocol 201 10.5.6 Select the Appropriate Design 202 10.5.6.1 Verifying Feasibility and Practicality of Factor Levels 202 10.5.6.2 Factorial Experimentation 202 10.5.6.3 The First Validation Experiment 203 10.5.6.4 Analysis: Developing a Regression Model 204 10.5.6.5 Software Comparison 204 10.6 Conclusion 205 Acknowledgments 205 Disclaimer 205 References 205 11 Total Cost of Ownership (TOC): An Approach for Estimating UMAS Costs 207 11.1 Introduction 207 11.2 Life Cycle Models 208 11.2.1 DoD 5000 Acquisition Life Cycle 208 11.2.2 ISO 15288 Life Cycle 208 11.3 Cost Estimation Methods 210 11.3.1 Case Study and Analogy 210 11.3.2 Bottom
Up and Activity Based 211 11.3.3 Parametric Modeling 212 11.4 UMAS Product Breakdown Structure 212 11.4.1 Special Considerations 212 11.4.1.1 Mission Requirements 214 11.4.2 System Capabilities 214 11.4.3 Payloads 214 11.5 Cost Drivers and Parametric Cost Models 215 11.5.1 Cost Drivers for Estimating Development Costs 215 11.5.1.1 Hardware 215 11.5.1.2 Software 218 11.5.1.3 Systems Engineering and Project Management 218 11.5.1.4 Performance
Based Cost Estimating Relationship 220 11.5.1.5 Weight
Based Cost Estimating Relationship 223 11.5.2 Proposed Cost Drivers for DoD 5000.02 Phase Operations and Support 224 11.5.2.1 Logistics - Transition from Contractor Life Support (CLS) to Organic Capabilities 224 11.5.2.2 Training 224 11.5.2.3 Operations - Manned Unmanned Systems Teaming (MUM
T) 225 11.6 Considerations for Estimating Unmanned Ground Vehicle Costs 225 11.7 Additional Considerations for UMAS Cost Estimation 230 11.7.1 Test and Evaluation 230 11.7.2 Demonstration 230 11.8 Conclusion 230 Acknowledgments 231 References 231 12 Logistics Support for Unmanned Systems 233 12.1 Introduction 233 12.2 Appreciating Logistics Support for Unmanned Systems 233 12.2.1 Logistics 234 12.2.2 Operations Research and Logistics 236 12.2.3 Unmanned Systems 240 12.3 Challenges to Logistics Support for Unmanned Systems 242 12.3.1 Immediate Challenges 242 12.3.2 Future Challenges 242 12.4 Grouping the Logistics Challenges for Analysis and Development 243 12.4.1 Group A - No Change to Logistics Support 243 12.4.2 Group B - Unmanned Systems Replacing Manned Systems and Their Logistics Support Frameworks 244 12.4.3 Group C - Major Changes to Unmanned Systems Logistics 247 12.5 Further Considerations 248 12.6 Conclusions 251 References 251 13 Organizing for Improved Effectiveness in Networked Operations 255 13.1 Introduction 255 13.2 Understanding the IACM 256 13.3 An Agent
Based Simulation Representation of the IACM 259 13.4 Structure of the Experiment 260 13.5 Initial Experiment 264 13.6 Expanding the Experiment 265 13.7 Conclusion 269 Disclaimer 270 References 270 14 An Exploration of Performance Distributions in Collectives 271 14.1 Introduction 271 14.2 Who Shoots How Many? 272 14.3 Baseball Plays as Individual and Networked Performance 273 14.4 Analytical Questions 275 14.5 Imparity Statistics in Major League Baseball Data 277 14.5.1 Individual Performance in Major League Baseball 278 14.5.2 Interconnected Performance in Major League Baseball 281 14.6 Conclusions 285 Acknowledgments 286 References 286 15 Distributed Combat Power: The Application of Salvo Theory to Unmanned Systems 287 15.1 Introduction 287 15.2 Salvo Theory 288 15.2.1 The Salvo Equations 288 15.2.2 Interpreting Damage 289 15.3 Salvo Warfare with Unmanned Systems 290 15.4 The Salvo Exchange Set and Combat Entropy 291 15.5 Tactical Considerations 292 15.6 Conclusion 293 References 294 Index 295
Transit Vigilant Covering Tour Problem for Routing Unmanned Ground Vehicles 7 2.1 Introduction 7 2.2 Background 8 2.3 CTP for UGV Coverage 9 2.4 The In
Transit Vigilant Covering Tour Problem 9 2.5 Mathematical Formulation 11 2.6 Extensions to Multiple Vehicles 14 2.7 Empirical Study 15 2.8 Analysis of Results 21 2.9 Other Extensions 24 2.10 Conclusions 25 Author Statement 25 References 25 3 Near
Optimal Assignment of UAVs to Targets Using a Market
Based Approach 27 3.1 Introduction 27 3.2 Problem Formulation 29 3.2.1 Inputs 29 3.2.2 Various Objective Functions 29 3.2.3 Outputs 31 3.3 Literature 31 3.3.1 Solutions to the MDVRP Variants 31 3.3.2 Market
Based Techniques 33 3.4 The Market
Based Solution 34 3.4.1 The Basic Market Solution 36 3.4.2 The Hierarchical Market 37 3.4.2.1 Motivation and Rationale 37 3.4.2.2 Algorithm Details 40 3.4.3 Adaptations for the Max
Pro Case 41 3.4.4 Summary 41 3.5 Results 42 3.5.1 Optimizing for Fuel
Consumption (Min
Sum) 43 3.5.2 Optimizing for Time (Min
Max) 44 3.5.3 Optimizing for Prioritized Targets (Max
Pro) 47 3.6 Recommendations for Implementation 51 3.7 Conclusions 52 Appendix 3.A A Mixed Integer Linear Programming (MILP) Formulation 53 3.A.1 Sub-tour Elimination Constraints 54 References 55 4 Considering Mine Countermeasures Exploratory Operations Conducted by Autonomous Underwater Vehicles 59 4.1 Background 59 4.2 Assumptions 61 4.3 Measures of Performance 62 4.4 Preliminary Results 64 4.5 Concepts of Operations 64 4.5.1 Gaps in Coverage 64 4.5.2 Aspect Angle Degradation 64 4.6 Optimality with Two Different Angular Observations 65 4.7 Optimality with N Different Angular Observations 66 4.8 Modeling and Algorithms 67 4.8.1 Monte Carlo Simulation 67 4.8.2 Deterministic Model 67 4.9 Random Search Formula Adapted to AUVs 68 4.10 Mine Countermeasures Exploratory Operations 70 4.11 Numerical Results 71 4.12 Non
uniform Mine Density Distributions 72 4.13 Conclusion 74 Appendix 4.A Optimal Observation Angle between Two AUV Legs 75 Appendix 4.B Probabilities of Detection 78 References 79 5 Optical Search by Unmanned Aerial Vehicles: Fauna Detection Case Study 81 5.1 Introduction 81 5.2 Search Planning for Unmanned Sensing Operations 82 5.2.1 Preliminary Flight Analysis 84 5.2.2 Flight Geometry Control 85 5.2.3 Images and Mosaics 86 5.2.4 Digital Analysis and Identification of Elements 88 5.3 Results 91 5.4 Conclusions 92 Acknowledgments 94 References 94 6 A Flight Time Approximation Model for Unmanned Aerial Vehicles: Estimating the Effects of Path Variations and Wind 95 Nomenclature 95 6.1 Introduction 96 6.2 Problem Statement 97 6.3 Literature Review 97 6.3.1 Flight Time Approximation Models 97 6.3.2 Additional Task Types to Consider 98 6.3.3 Wind Effects 99 6.4 Flight Time Approximation Model Development 99 6.4.1 Required Mathematical Calculations 100 6.4.2 Model Comparisons 101 6.4.3 Encountered Problems and Solutions 102 6.5 Additional Task Types 103 6.5.1 Radius of Sight Task 103 6.5.2 Loitering Task 105 6.6 Adding Wind Effects 108 6.6.1 Implementing the Fuel Burn Rate Model 110 6.7 Computational Expense of the Final Model 111 6.7.1 Model Runtime Analysis 111 6.7.2 Actual versus Expected Flight Times 113 6.8 Conclusions and Future Work 115 Acknowledgments 117 References 117 7 Impacts of Unmanned Ground Vehicles on Combined Arms Team Performance 119 7.1 Introduction 119 7.2 Study Problem 120 7.2.1 Terrain 120 7.2.2 Vehicle Options 122 7.2.3 Forces 122 7.2.3.1 Experimental Force 123 7.2.3.2 Opposition Force 123 7.2.3.3 Civilian Elements 123 7.2.4 Mission 124 7.3 Study Methods 125 7.3.1 Closed
Loop Simulation 125 7.3.2 Study Measures 126 7.3.3 System Comparison Approach 128 7.4 Study Results 128 7.4.1 Basic Casualty Results 128 7.4.1.1 Low Density Urban Terrain Casualty Only Results 128 7.4.1.2 Dense Urban Terrain Casualty
Only Results 130 7.4.2 Complete Measures Results 131 7.4.2.1 Low Density Urban Terrain Results 131 7.4.2.2 Dense Urban Terrain Results 132 7.4.2.3 Comparison of Low and High Density Urban Results 133 7.4.3 Casualty versus Full Measures Comparison 135 7.5 Discussion 136 References 137 8 Processing, Exploitation and Dissemination: When is Aided/Automated Target Recognition "Good Enough" for Operational Use? 139 8.1 Introduction 139 8.2 Background 140 8.2.1 Operational Context and Technical Issues 140 8.2.2 Previous Investigations 141 8.3 Analysis 143 8.3.1 Modeling the Mission 144 8.3.2 Modeling the Specific Concept of Operations 145 8.3.3 Probability of Acquiring the Target under the Concept of Operations 146 8.3.4 Rational Selection between Aided/Automated Target Recognition and Extended Human Sensing 147 8.3.5 Finding the Threshold at which Automation is Rational 148 8.3.6 Example 148 8.4 Conclusion 149 Acknowledgments 151 Appendix 8.A 151 Ensuring
[Q ] * decreases as
* increases 152 References 152 9 Analyzing a Design Continuum for Automated Military Convoy Operations 155 9.1 Introduction 155 9.2 Definition Development 156 9.2.1 Human Input Proportion (H) 156 9.2.2 Interaction Frequency 157 9.2.3 Complexity of Instructions/Tasks 157 9.2.4 Robotic Decision
Making Ability (R) 157 9.3 Automation Continuum 157 9.3.1 Status Quo (SQ) 158 9.3.2 Remote Control (RC) 158 9.3.3 Tele
Operation (TO) 158 9.3.4 Driver Warning (DW) 158 9.3.5 Driver Assist (DA) 158 9.3.6 Leader
Follower (LF) 159 9.3.6.1 Tethered Leader
Follower (LF1) 159 9.3.6.2 Un
tethered Leader
Follower (LF2) 159 9.3.6.3 Un
tethered/Unmanned/Pre
driven Leader
Follower (LF3) 159 9.3.6.4 Un
tethered/Unmanned/Uploaded Leader
Follower (LF4) 159 9.3.7 Waypoint (WA) 159 9.3.7.1 Pre
recorded "Breadcrumb" Waypoint (WA1) 160 9.3.7.2 Uploaded "Breadcrumb" Waypoint (WA2) 160 9.3.8 Full Automation (FA) 160 9.3.8.1 Uploaded "Breadcrumbs" with Route Suggestion Full Automation (FA1) 160 9.3.8.2 Self
Determining Full Automation (FA2) 160 9.4 Mathematically Modeling Human Input Proportion (H) versus System Configuration 161 9.4.1 Modeling H versus System Configuration Methodology 161 9.4.2 Analyzing the Results of Modeling H versus System Configuration 165 9.4.3 Partitioning the Automation Continuum for H versus System Configuration into Regimes and Analyzing the Results 168 9.5 Mathematically Modeling Robotic Decision
Making Ability (R) versus System Configuration 169 9.5.1 Modeling R versus System Configuration Methodology 169 9.5.2 Mathematically Modeling R versus System Configuration When Weighted by H 171 9.5.3 Partitioning the Automation Continuum for R (Weighted by H) versus System Configuration into Regimes 175 9.5.4 Summarizing the Results of Modeling H versus System Configuration and R versus System Configuration When Weighted by H 177 9.6 Mathematically Modeling H and R 178 9.6.1 Analyzing the Results of Modeling H versus R 178 9.7 Conclusion 180 9.A System Configurations 180 10 Experimental Design for Unmanned Aerial Systems Analysis: Bringing Statistical Rigor to UAS Testing 187 10.1 Introduction 187 10.2 Some UAS History 188 10.3 Statistical Background for Experimental Planning 189 10.4 Planning the UAS Experiment 192 10.4.1 General Planning Guidelines 192 10.4.2 Planning Guidelines for UAS Testing 193 10.4.2.1 Determine Specific Questions to Answer 194 10.4.2.2 Determine Role of the Human Operator 194 10.4.2.3 Define and Delineate Factors of Concern for the Study 195 10.4.2.4 Determine and Correlate Response Data 196 10.4.2.5 Select an Appropriate Design 196 10.4.2.6 Define the Test Execution Strategy 198 10.5 Applications of the UAS Planning Guidelines 199 10.5.1 Determine the Specific Research Questions 199 10.5.2 Determining the Role of Human Operators 199 10.5.3 Determine the Response Data 200 10.5.4 Define the Experimental Factors 200 10.5.5 Establishing the Experimental Protocol 201 10.5.6 Select the Appropriate Design 202 10.5.6.1 Verifying Feasibility and Practicality of Factor Levels 202 10.5.6.2 Factorial Experimentation 202 10.5.6.3 The First Validation Experiment 203 10.5.6.4 Analysis: Developing a Regression Model 204 10.5.6.5 Software Comparison 204 10.6 Conclusion 205 Acknowledgments 205 Disclaimer 205 References 205 11 Total Cost of Ownership (TOC): An Approach for Estimating UMAS Costs 207 11.1 Introduction 207 11.2 Life Cycle Models 208 11.2.1 DoD 5000 Acquisition Life Cycle 208 11.2.2 ISO 15288 Life Cycle 208 11.3 Cost Estimation Methods 210 11.3.1 Case Study and Analogy 210 11.3.2 Bottom
Up and Activity Based 211 11.3.3 Parametric Modeling 212 11.4 UMAS Product Breakdown Structure 212 11.4.1 Special Considerations 212 11.4.1.1 Mission Requirements 214 11.4.2 System Capabilities 214 11.4.3 Payloads 214 11.5 Cost Drivers and Parametric Cost Models 215 11.5.1 Cost Drivers for Estimating Development Costs 215 11.5.1.1 Hardware 215 11.5.1.2 Software 218 11.5.1.3 Systems Engineering and Project Management 218 11.5.1.4 Performance
Based Cost Estimating Relationship 220 11.5.1.5 Weight
Based Cost Estimating Relationship 223 11.5.2 Proposed Cost Drivers for DoD 5000.02 Phase Operations and Support 224 11.5.2.1 Logistics - Transition from Contractor Life Support (CLS) to Organic Capabilities 224 11.5.2.2 Training 224 11.5.2.3 Operations - Manned Unmanned Systems Teaming (MUM
T) 225 11.6 Considerations for Estimating Unmanned Ground Vehicle Costs 225 11.7 Additional Considerations for UMAS Cost Estimation 230 11.7.1 Test and Evaluation 230 11.7.2 Demonstration 230 11.8 Conclusion 230 Acknowledgments 231 References 231 12 Logistics Support for Unmanned Systems 233 12.1 Introduction 233 12.2 Appreciating Logistics Support for Unmanned Systems 233 12.2.1 Logistics 234 12.2.2 Operations Research and Logistics 236 12.2.3 Unmanned Systems 240 12.3 Challenges to Logistics Support for Unmanned Systems 242 12.3.1 Immediate Challenges 242 12.3.2 Future Challenges 242 12.4 Grouping the Logistics Challenges for Analysis and Development 243 12.4.1 Group A - No Change to Logistics Support 243 12.4.2 Group B - Unmanned Systems Replacing Manned Systems and Their Logistics Support Frameworks 244 12.4.3 Group C - Major Changes to Unmanned Systems Logistics 247 12.5 Further Considerations 248 12.6 Conclusions 251 References 251 13 Organizing for Improved Effectiveness in Networked Operations 255 13.1 Introduction 255 13.2 Understanding the IACM 256 13.3 An Agent
Based Simulation Representation of the IACM 259 13.4 Structure of the Experiment 260 13.5 Initial Experiment 264 13.6 Expanding the Experiment 265 13.7 Conclusion 269 Disclaimer 270 References 270 14 An Exploration of Performance Distributions in Collectives 271 14.1 Introduction 271 14.2 Who Shoots How Many? 272 14.3 Baseball Plays as Individual and Networked Performance 273 14.4 Analytical Questions 275 14.5 Imparity Statistics in Major League Baseball Data 277 14.5.1 Individual Performance in Major League Baseball 278 14.5.2 Interconnected Performance in Major League Baseball 281 14.6 Conclusions 285 Acknowledgments 286 References 286 15 Distributed Combat Power: The Application of Salvo Theory to Unmanned Systems 287 15.1 Introduction 287 15.2 Salvo Theory 288 15.2.1 The Salvo Equations 288 15.2.2 Interpreting Damage 289 15.3 Salvo Warfare with Unmanned Systems 290 15.4 The Salvo Exchange Set and Combat Entropy 291 15.5 Tactical Considerations 292 15.6 Conclusion 293 References 294 Index 295
About the contributors xiii Acknowledgements xix 1 Introduction 1 1.1 Introduction 1 1.2 Background and Scope 3 1.3 About the Chapters 4 References 6 2 The In
Transit Vigilant Covering Tour Problem for Routing Unmanned Ground Vehicles 7 2.1 Introduction 7 2.2 Background 8 2.3 CTP for UGV Coverage 9 2.4 The In
Transit Vigilant Covering Tour Problem 9 2.5 Mathematical Formulation 11 2.6 Extensions to Multiple Vehicles 14 2.7 Empirical Study 15 2.8 Analysis of Results 21 2.9 Other Extensions 24 2.10 Conclusions 25 Author Statement 25 References 25 3 Near
Optimal Assignment of UAVs to Targets Using a Market
Based Approach 27 3.1 Introduction 27 3.2 Problem Formulation 29 3.2.1 Inputs 29 3.2.2 Various Objective Functions 29 3.2.3 Outputs 31 3.3 Literature 31 3.3.1 Solutions to the MDVRP Variants 31 3.3.2 Market
Based Techniques 33 3.4 The Market
Based Solution 34 3.4.1 The Basic Market Solution 36 3.4.2 The Hierarchical Market 37 3.4.2.1 Motivation and Rationale 37 3.4.2.2 Algorithm Details 40 3.4.3 Adaptations for the Max
Pro Case 41 3.4.4 Summary 41 3.5 Results 42 3.5.1 Optimizing for Fuel
Consumption (Min
Sum) 43 3.5.2 Optimizing for Time (Min
Max) 44 3.5.3 Optimizing for Prioritized Targets (Max
Pro) 47 3.6 Recommendations for Implementation 51 3.7 Conclusions 52 Appendix 3.A A Mixed Integer Linear Programming (MILP) Formulation 53 3.A.1 Sub-tour Elimination Constraints 54 References 55 4 Considering Mine Countermeasures Exploratory Operations Conducted by Autonomous Underwater Vehicles 59 4.1 Background 59 4.2 Assumptions 61 4.3 Measures of Performance 62 4.4 Preliminary Results 64 4.5 Concepts of Operations 64 4.5.1 Gaps in Coverage 64 4.5.2 Aspect Angle Degradation 64 4.6 Optimality with Two Different Angular Observations 65 4.7 Optimality with N Different Angular Observations 66 4.8 Modeling and Algorithms 67 4.8.1 Monte Carlo Simulation 67 4.8.2 Deterministic Model 67 4.9 Random Search Formula Adapted to AUVs 68 4.10 Mine Countermeasures Exploratory Operations 70 4.11 Numerical Results 71 4.12 Non
uniform Mine Density Distributions 72 4.13 Conclusion 74 Appendix 4.A Optimal Observation Angle between Two AUV Legs 75 Appendix 4.B Probabilities of Detection 78 References 79 5 Optical Search by Unmanned Aerial Vehicles: Fauna Detection Case Study 81 5.1 Introduction 81 5.2 Search Planning for Unmanned Sensing Operations 82 5.2.1 Preliminary Flight Analysis 84 5.2.2 Flight Geometry Control 85 5.2.3 Images and Mosaics 86 5.2.4 Digital Analysis and Identification of Elements 88 5.3 Results 91 5.4 Conclusions 92 Acknowledgments 94 References 94 6 A Flight Time Approximation Model for Unmanned Aerial Vehicles: Estimating the Effects of Path Variations and Wind 95 Nomenclature 95 6.1 Introduction 96 6.2 Problem Statement 97 6.3 Literature Review 97 6.3.1 Flight Time Approximation Models 97 6.3.2 Additional Task Types to Consider 98 6.3.3 Wind Effects 99 6.4 Flight Time Approximation Model Development 99 6.4.1 Required Mathematical Calculations 100 6.4.2 Model Comparisons 101 6.4.3 Encountered Problems and Solutions 102 6.5 Additional Task Types 103 6.5.1 Radius of Sight Task 103 6.5.2 Loitering Task 105 6.6 Adding Wind Effects 108 6.6.1 Implementing the Fuel Burn Rate Model 110 6.7 Computational Expense of the Final Model 111 6.7.1 Model Runtime Analysis 111 6.7.2 Actual versus Expected Flight Times 113 6.8 Conclusions and Future Work 115 Acknowledgments 117 References 117 7 Impacts of Unmanned Ground Vehicles on Combined Arms Team Performance 119 7.1 Introduction 119 7.2 Study Problem 120 7.2.1 Terrain 120 7.2.2 Vehicle Options 122 7.2.3 Forces 122 7.2.3.1 Experimental Force 123 7.2.3.2 Opposition Force 123 7.2.3.3 Civilian Elements 123 7.2.4 Mission 124 7.3 Study Methods 125 7.3.1 Closed
Loop Simulation 125 7.3.2 Study Measures 126 7.3.3 System Comparison Approach 128 7.4 Study Results 128 7.4.1 Basic Casualty Results 128 7.4.1.1 Low Density Urban Terrain Casualty Only Results 128 7.4.1.2 Dense Urban Terrain Casualty
Only Results 130 7.4.2 Complete Measures Results 131 7.4.2.1 Low Density Urban Terrain Results 131 7.4.2.2 Dense Urban Terrain Results 132 7.4.2.3 Comparison of Low and High Density Urban Results 133 7.4.3 Casualty versus Full Measures Comparison 135 7.5 Discussion 136 References 137 8 Processing, Exploitation and Dissemination: When is Aided/Automated Target Recognition "Good Enough" for Operational Use? 139 8.1 Introduction 139 8.2 Background 140 8.2.1 Operational Context and Technical Issues 140 8.2.2 Previous Investigations 141 8.3 Analysis 143 8.3.1 Modeling the Mission 144 8.3.2 Modeling the Specific Concept of Operations 145 8.3.3 Probability of Acquiring the Target under the Concept of Operations 146 8.3.4 Rational Selection between Aided/Automated Target Recognition and Extended Human Sensing 147 8.3.5 Finding the Threshold at which Automation is Rational 148 8.3.6 Example 148 8.4 Conclusion 149 Acknowledgments 151 Appendix 8.A 151 Ensuring
[Q ] * decreases as
* increases 152 References 152 9 Analyzing a Design Continuum for Automated Military Convoy Operations 155 9.1 Introduction 155 9.2 Definition Development 156 9.2.1 Human Input Proportion (H) 156 9.2.2 Interaction Frequency 157 9.2.3 Complexity of Instructions/Tasks 157 9.2.4 Robotic Decision
Making Ability (R) 157 9.3 Automation Continuum 157 9.3.1 Status Quo (SQ) 158 9.3.2 Remote Control (RC) 158 9.3.3 Tele
Operation (TO) 158 9.3.4 Driver Warning (DW) 158 9.3.5 Driver Assist (DA) 158 9.3.6 Leader
Follower (LF) 159 9.3.6.1 Tethered Leader
Follower (LF1) 159 9.3.6.2 Un
tethered Leader
Follower (LF2) 159 9.3.6.3 Un
tethered/Unmanned/Pre
driven Leader
Follower (LF3) 159 9.3.6.4 Un
tethered/Unmanned/Uploaded Leader
Follower (LF4) 159 9.3.7 Waypoint (WA) 159 9.3.7.1 Pre
recorded "Breadcrumb" Waypoint (WA1) 160 9.3.7.2 Uploaded "Breadcrumb" Waypoint (WA2) 160 9.3.8 Full Automation (FA) 160 9.3.8.1 Uploaded "Breadcrumbs" with Route Suggestion Full Automation (FA1) 160 9.3.8.2 Self
Determining Full Automation (FA2) 160 9.4 Mathematically Modeling Human Input Proportion (H) versus System Configuration 161 9.4.1 Modeling H versus System Configuration Methodology 161 9.4.2 Analyzing the Results of Modeling H versus System Configuration 165 9.4.3 Partitioning the Automation Continuum for H versus System Configuration into Regimes and Analyzing the Results 168 9.5 Mathematically Modeling Robotic Decision
Making Ability (R) versus System Configuration 169 9.5.1 Modeling R versus System Configuration Methodology 169 9.5.2 Mathematically Modeling R versus System Configuration When Weighted by H 171 9.5.3 Partitioning the Automation Continuum for R (Weighted by H) versus System Configuration into Regimes 175 9.5.4 Summarizing the Results of Modeling H versus System Configuration and R versus System Configuration When Weighted by H 177 9.6 Mathematically Modeling H and R 178 9.6.1 Analyzing the Results of Modeling H versus R 178 9.7 Conclusion 180 9.A System Configurations 180 10 Experimental Design for Unmanned Aerial Systems Analysis: Bringing Statistical Rigor to UAS Testing 187 10.1 Introduction 187 10.2 Some UAS History 188 10.3 Statistical Background for Experimental Planning 189 10.4 Planning the UAS Experiment 192 10.4.1 General Planning Guidelines 192 10.4.2 Planning Guidelines for UAS Testing 193 10.4.2.1 Determine Specific Questions to Answer 194 10.4.2.2 Determine Role of the Human Operator 194 10.4.2.3 Define and Delineate Factors of Concern for the Study 195 10.4.2.4 Determine and Correlate Response Data 196 10.4.2.5 Select an Appropriate Design 196 10.4.2.6 Define the Test Execution Strategy 198 10.5 Applications of the UAS Planning Guidelines 199 10.5.1 Determine the Specific Research Questions 199 10.5.2 Determining the Role of Human Operators 199 10.5.3 Determine the Response Data 200 10.5.4 Define the Experimental Factors 200 10.5.5 Establishing the Experimental Protocol 201 10.5.6 Select the Appropriate Design 202 10.5.6.1 Verifying Feasibility and Practicality of Factor Levels 202 10.5.6.2 Factorial Experimentation 202 10.5.6.3 The First Validation Experiment 203 10.5.6.4 Analysis: Developing a Regression Model 204 10.5.6.5 Software Comparison 204 10.6 Conclusion 205 Acknowledgments 205 Disclaimer 205 References 205 11 Total Cost of Ownership (TOC): An Approach for Estimating UMAS Costs 207 11.1 Introduction 207 11.2 Life Cycle Models 208 11.2.1 DoD 5000 Acquisition Life Cycle 208 11.2.2 ISO 15288 Life Cycle 208 11.3 Cost Estimation Methods 210 11.3.1 Case Study and Analogy 210 11.3.2 Bottom
Up and Activity Based 211 11.3.3 Parametric Modeling 212 11.4 UMAS Product Breakdown Structure 212 11.4.1 Special Considerations 212 11.4.1.1 Mission Requirements 214 11.4.2 System Capabilities 214 11.4.3 Payloads 214 11.5 Cost Drivers and Parametric Cost Models 215 11.5.1 Cost Drivers for Estimating Development Costs 215 11.5.1.1 Hardware 215 11.5.1.2 Software 218 11.5.1.3 Systems Engineering and Project Management 218 11.5.1.4 Performance
Based Cost Estimating Relationship 220 11.5.1.5 Weight
Based Cost Estimating Relationship 223 11.5.2 Proposed Cost Drivers for DoD 5000.02 Phase Operations and Support 224 11.5.2.1 Logistics - Transition from Contractor Life Support (CLS) to Organic Capabilities 224 11.5.2.2 Training 224 11.5.2.3 Operations - Manned Unmanned Systems Teaming (MUM
T) 225 11.6 Considerations for Estimating Unmanned Ground Vehicle Costs 225 11.7 Additional Considerations for UMAS Cost Estimation 230 11.7.1 Test and Evaluation 230 11.7.2 Demonstration 230 11.8 Conclusion 230 Acknowledgments 231 References 231 12 Logistics Support for Unmanned Systems 233 12.1 Introduction 233 12.2 Appreciating Logistics Support for Unmanned Systems 233 12.2.1 Logistics 234 12.2.2 Operations Research and Logistics 236 12.2.3 Unmanned Systems 240 12.3 Challenges to Logistics Support for Unmanned Systems 242 12.3.1 Immediate Challenges 242 12.3.2 Future Challenges 242 12.4 Grouping the Logistics Challenges for Analysis and Development 243 12.4.1 Group A - No Change to Logistics Support 243 12.4.2 Group B - Unmanned Systems Replacing Manned Systems and Their Logistics Support Frameworks 244 12.4.3 Group C - Major Changes to Unmanned Systems Logistics 247 12.5 Further Considerations 248 12.6 Conclusions 251 References 251 13 Organizing for Improved Effectiveness in Networked Operations 255 13.1 Introduction 255 13.2 Understanding the IACM 256 13.3 An Agent
Based Simulation Representation of the IACM 259 13.4 Structure of the Experiment 260 13.5 Initial Experiment 264 13.6 Expanding the Experiment 265 13.7 Conclusion 269 Disclaimer 270 References 270 14 An Exploration of Performance Distributions in Collectives 271 14.1 Introduction 271 14.2 Who Shoots How Many? 272 14.3 Baseball Plays as Individual and Networked Performance 273 14.4 Analytical Questions 275 14.5 Imparity Statistics in Major League Baseball Data 277 14.5.1 Individual Performance in Major League Baseball 278 14.5.2 Interconnected Performance in Major League Baseball 281 14.6 Conclusions 285 Acknowledgments 286 References 286 15 Distributed Combat Power: The Application of Salvo Theory to Unmanned Systems 287 15.1 Introduction 287 15.2 Salvo Theory 288 15.2.1 The Salvo Equations 288 15.2.2 Interpreting Damage 289 15.3 Salvo Warfare with Unmanned Systems 290 15.4 The Salvo Exchange Set and Combat Entropy 291 15.5 Tactical Considerations 292 15.6 Conclusion 293 References 294 Index 295
Transit Vigilant Covering Tour Problem for Routing Unmanned Ground Vehicles 7 2.1 Introduction 7 2.2 Background 8 2.3 CTP for UGV Coverage 9 2.4 The In
Transit Vigilant Covering Tour Problem 9 2.5 Mathematical Formulation 11 2.6 Extensions to Multiple Vehicles 14 2.7 Empirical Study 15 2.8 Analysis of Results 21 2.9 Other Extensions 24 2.10 Conclusions 25 Author Statement 25 References 25 3 Near
Optimal Assignment of UAVs to Targets Using a Market
Based Approach 27 3.1 Introduction 27 3.2 Problem Formulation 29 3.2.1 Inputs 29 3.2.2 Various Objective Functions 29 3.2.3 Outputs 31 3.3 Literature 31 3.3.1 Solutions to the MDVRP Variants 31 3.3.2 Market
Based Techniques 33 3.4 The Market
Based Solution 34 3.4.1 The Basic Market Solution 36 3.4.2 The Hierarchical Market 37 3.4.2.1 Motivation and Rationale 37 3.4.2.2 Algorithm Details 40 3.4.3 Adaptations for the Max
Pro Case 41 3.4.4 Summary 41 3.5 Results 42 3.5.1 Optimizing for Fuel
Consumption (Min
Sum) 43 3.5.2 Optimizing for Time (Min
Max) 44 3.5.3 Optimizing for Prioritized Targets (Max
Pro) 47 3.6 Recommendations for Implementation 51 3.7 Conclusions 52 Appendix 3.A A Mixed Integer Linear Programming (MILP) Formulation 53 3.A.1 Sub-tour Elimination Constraints 54 References 55 4 Considering Mine Countermeasures Exploratory Operations Conducted by Autonomous Underwater Vehicles 59 4.1 Background 59 4.2 Assumptions 61 4.3 Measures of Performance 62 4.4 Preliminary Results 64 4.5 Concepts of Operations 64 4.5.1 Gaps in Coverage 64 4.5.2 Aspect Angle Degradation 64 4.6 Optimality with Two Different Angular Observations 65 4.7 Optimality with N Different Angular Observations 66 4.8 Modeling and Algorithms 67 4.8.1 Monte Carlo Simulation 67 4.8.2 Deterministic Model 67 4.9 Random Search Formula Adapted to AUVs 68 4.10 Mine Countermeasures Exploratory Operations 70 4.11 Numerical Results 71 4.12 Non
uniform Mine Density Distributions 72 4.13 Conclusion 74 Appendix 4.A Optimal Observation Angle between Two AUV Legs 75 Appendix 4.B Probabilities of Detection 78 References 79 5 Optical Search by Unmanned Aerial Vehicles: Fauna Detection Case Study 81 5.1 Introduction 81 5.2 Search Planning for Unmanned Sensing Operations 82 5.2.1 Preliminary Flight Analysis 84 5.2.2 Flight Geometry Control 85 5.2.3 Images and Mosaics 86 5.2.4 Digital Analysis and Identification of Elements 88 5.3 Results 91 5.4 Conclusions 92 Acknowledgments 94 References 94 6 A Flight Time Approximation Model for Unmanned Aerial Vehicles: Estimating the Effects of Path Variations and Wind 95 Nomenclature 95 6.1 Introduction 96 6.2 Problem Statement 97 6.3 Literature Review 97 6.3.1 Flight Time Approximation Models 97 6.3.2 Additional Task Types to Consider 98 6.3.3 Wind Effects 99 6.4 Flight Time Approximation Model Development 99 6.4.1 Required Mathematical Calculations 100 6.4.2 Model Comparisons 101 6.4.3 Encountered Problems and Solutions 102 6.5 Additional Task Types 103 6.5.1 Radius of Sight Task 103 6.5.2 Loitering Task 105 6.6 Adding Wind Effects 108 6.6.1 Implementing the Fuel Burn Rate Model 110 6.7 Computational Expense of the Final Model 111 6.7.1 Model Runtime Analysis 111 6.7.2 Actual versus Expected Flight Times 113 6.8 Conclusions and Future Work 115 Acknowledgments 117 References 117 7 Impacts of Unmanned Ground Vehicles on Combined Arms Team Performance 119 7.1 Introduction 119 7.2 Study Problem 120 7.2.1 Terrain 120 7.2.2 Vehicle Options 122 7.2.3 Forces 122 7.2.3.1 Experimental Force 123 7.2.3.2 Opposition Force 123 7.2.3.3 Civilian Elements 123 7.2.4 Mission 124 7.3 Study Methods 125 7.3.1 Closed
Loop Simulation 125 7.3.2 Study Measures 126 7.3.3 System Comparison Approach 128 7.4 Study Results 128 7.4.1 Basic Casualty Results 128 7.4.1.1 Low Density Urban Terrain Casualty Only Results 128 7.4.1.2 Dense Urban Terrain Casualty
Only Results 130 7.4.2 Complete Measures Results 131 7.4.2.1 Low Density Urban Terrain Results 131 7.4.2.2 Dense Urban Terrain Results 132 7.4.2.3 Comparison of Low and High Density Urban Results 133 7.4.3 Casualty versus Full Measures Comparison 135 7.5 Discussion 136 References 137 8 Processing, Exploitation and Dissemination: When is Aided/Automated Target Recognition "Good Enough" for Operational Use? 139 8.1 Introduction 139 8.2 Background 140 8.2.1 Operational Context and Technical Issues 140 8.2.2 Previous Investigations 141 8.3 Analysis 143 8.3.1 Modeling the Mission 144 8.3.2 Modeling the Specific Concept of Operations 145 8.3.3 Probability of Acquiring the Target under the Concept of Operations 146 8.3.4 Rational Selection between Aided/Automated Target Recognition and Extended Human Sensing 147 8.3.5 Finding the Threshold at which Automation is Rational 148 8.3.6 Example 148 8.4 Conclusion 149 Acknowledgments 151 Appendix 8.A 151 Ensuring
[Q ] * decreases as
* increases 152 References 152 9 Analyzing a Design Continuum for Automated Military Convoy Operations 155 9.1 Introduction 155 9.2 Definition Development 156 9.2.1 Human Input Proportion (H) 156 9.2.2 Interaction Frequency 157 9.2.3 Complexity of Instructions/Tasks 157 9.2.4 Robotic Decision
Making Ability (R) 157 9.3 Automation Continuum 157 9.3.1 Status Quo (SQ) 158 9.3.2 Remote Control (RC) 158 9.3.3 Tele
Operation (TO) 158 9.3.4 Driver Warning (DW) 158 9.3.5 Driver Assist (DA) 158 9.3.6 Leader
Follower (LF) 159 9.3.6.1 Tethered Leader
Follower (LF1) 159 9.3.6.2 Un
tethered Leader
Follower (LF2) 159 9.3.6.3 Un
tethered/Unmanned/Pre
driven Leader
Follower (LF3) 159 9.3.6.4 Un
tethered/Unmanned/Uploaded Leader
Follower (LF4) 159 9.3.7 Waypoint (WA) 159 9.3.7.1 Pre
recorded "Breadcrumb" Waypoint (WA1) 160 9.3.7.2 Uploaded "Breadcrumb" Waypoint (WA2) 160 9.3.8 Full Automation (FA) 160 9.3.8.1 Uploaded "Breadcrumbs" with Route Suggestion Full Automation (FA1) 160 9.3.8.2 Self
Determining Full Automation (FA2) 160 9.4 Mathematically Modeling Human Input Proportion (H) versus System Configuration 161 9.4.1 Modeling H versus System Configuration Methodology 161 9.4.2 Analyzing the Results of Modeling H versus System Configuration 165 9.4.3 Partitioning the Automation Continuum for H versus System Configuration into Regimes and Analyzing the Results 168 9.5 Mathematically Modeling Robotic Decision
Making Ability (R) versus System Configuration 169 9.5.1 Modeling R versus System Configuration Methodology 169 9.5.2 Mathematically Modeling R versus System Configuration When Weighted by H 171 9.5.3 Partitioning the Automation Continuum for R (Weighted by H) versus System Configuration into Regimes 175 9.5.4 Summarizing the Results of Modeling H versus System Configuration and R versus System Configuration When Weighted by H 177 9.6 Mathematically Modeling H and R 178 9.6.1 Analyzing the Results of Modeling H versus R 178 9.7 Conclusion 180 9.A System Configurations 180 10 Experimental Design for Unmanned Aerial Systems Analysis: Bringing Statistical Rigor to UAS Testing 187 10.1 Introduction 187 10.2 Some UAS History 188 10.3 Statistical Background for Experimental Planning 189 10.4 Planning the UAS Experiment 192 10.4.1 General Planning Guidelines 192 10.4.2 Planning Guidelines for UAS Testing 193 10.4.2.1 Determine Specific Questions to Answer 194 10.4.2.2 Determine Role of the Human Operator 194 10.4.2.3 Define and Delineate Factors of Concern for the Study 195 10.4.2.4 Determine and Correlate Response Data 196 10.4.2.5 Select an Appropriate Design 196 10.4.2.6 Define the Test Execution Strategy 198 10.5 Applications of the UAS Planning Guidelines 199 10.5.1 Determine the Specific Research Questions 199 10.5.2 Determining the Role of Human Operators 199 10.5.3 Determine the Response Data 200 10.5.4 Define the Experimental Factors 200 10.5.5 Establishing the Experimental Protocol 201 10.5.6 Select the Appropriate Design 202 10.5.6.1 Verifying Feasibility and Practicality of Factor Levels 202 10.5.6.2 Factorial Experimentation 202 10.5.6.3 The First Validation Experiment 203 10.5.6.4 Analysis: Developing a Regression Model 204 10.5.6.5 Software Comparison 204 10.6 Conclusion 205 Acknowledgments 205 Disclaimer 205 References 205 11 Total Cost of Ownership (TOC): An Approach for Estimating UMAS Costs 207 11.1 Introduction 207 11.2 Life Cycle Models 208 11.2.1 DoD 5000 Acquisition Life Cycle 208 11.2.2 ISO 15288 Life Cycle 208 11.3 Cost Estimation Methods 210 11.3.1 Case Study and Analogy 210 11.3.2 Bottom
Up and Activity Based 211 11.3.3 Parametric Modeling 212 11.4 UMAS Product Breakdown Structure 212 11.4.1 Special Considerations 212 11.4.1.1 Mission Requirements 214 11.4.2 System Capabilities 214 11.4.3 Payloads 214 11.5 Cost Drivers and Parametric Cost Models 215 11.5.1 Cost Drivers for Estimating Development Costs 215 11.5.1.1 Hardware 215 11.5.1.2 Software 218 11.5.1.3 Systems Engineering and Project Management 218 11.5.1.4 Performance
Based Cost Estimating Relationship 220 11.5.1.5 Weight
Based Cost Estimating Relationship 223 11.5.2 Proposed Cost Drivers for DoD 5000.02 Phase Operations and Support 224 11.5.2.1 Logistics - Transition from Contractor Life Support (CLS) to Organic Capabilities 224 11.5.2.2 Training 224 11.5.2.3 Operations - Manned Unmanned Systems Teaming (MUM
T) 225 11.6 Considerations for Estimating Unmanned Ground Vehicle Costs 225 11.7 Additional Considerations for UMAS Cost Estimation 230 11.7.1 Test and Evaluation 230 11.7.2 Demonstration 230 11.8 Conclusion 230 Acknowledgments 231 References 231 12 Logistics Support for Unmanned Systems 233 12.1 Introduction 233 12.2 Appreciating Logistics Support for Unmanned Systems 233 12.2.1 Logistics 234 12.2.2 Operations Research and Logistics 236 12.2.3 Unmanned Systems 240 12.3 Challenges to Logistics Support for Unmanned Systems 242 12.3.1 Immediate Challenges 242 12.3.2 Future Challenges 242 12.4 Grouping the Logistics Challenges for Analysis and Development 243 12.4.1 Group A - No Change to Logistics Support 243 12.4.2 Group B - Unmanned Systems Replacing Manned Systems and Their Logistics Support Frameworks 244 12.4.3 Group C - Major Changes to Unmanned Systems Logistics 247 12.5 Further Considerations 248 12.6 Conclusions 251 References 251 13 Organizing for Improved Effectiveness in Networked Operations 255 13.1 Introduction 255 13.2 Understanding the IACM 256 13.3 An Agent
Based Simulation Representation of the IACM 259 13.4 Structure of the Experiment 260 13.5 Initial Experiment 264 13.6 Expanding the Experiment 265 13.7 Conclusion 269 Disclaimer 270 References 270 14 An Exploration of Performance Distributions in Collectives 271 14.1 Introduction 271 14.2 Who Shoots How Many? 272 14.3 Baseball Plays as Individual and Networked Performance 273 14.4 Analytical Questions 275 14.5 Imparity Statistics in Major League Baseball Data 277 14.5.1 Individual Performance in Major League Baseball 278 14.5.2 Interconnected Performance in Major League Baseball 281 14.6 Conclusions 285 Acknowledgments 286 References 286 15 Distributed Combat Power: The Application of Salvo Theory to Unmanned Systems 287 15.1 Introduction 287 15.2 Salvo Theory 288 15.2.1 The Salvo Equations 288 15.2.2 Interpreting Damage 289 15.3 Salvo Warfare with Unmanned Systems 290 15.4 The Salvo Exchange Set and Combat Entropy 291 15.5 Tactical Considerations 292 15.6 Conclusion 293 References 294 Index 295