George F. Elmasry
Tactical Wireless Communications and Networks (eBook, PDF)
Design Concepts and Challenges
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George F. Elmasry
Tactical Wireless Communications and Networks (eBook, PDF)
Design Concepts and Challenges
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Providing a complete description of modern tactical military communications and networks technology, this book systematically compares tactical military communications techniques with their commercial equivalents, pointing out similarities and differences. In particular it examines each layer of the protocol stack and shows how specific tactical and security requirements result in changes from the commercial approach. The author systematically leads readers through this complex topic, firstly providing background on the architectural approach upon which the analysis will be based, and then…mehr
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Providing a complete description of modern tactical military communications and networks technology, this book systematically compares tactical military communications techniques with their commercial equivalents, pointing out similarities and differences. In particular it examines each layer of the protocol stack and shows how specific tactical and security requirements result in changes from the commercial approach. The author systematically leads readers through this complex topic, firstly providing background on the architectural approach upon which the analysis will be based, and then going into detail on tactical wireless communications and networking technologies and techniques. * Structured progressively: for readers needing an overall view; for those looking at the communications aspects (lower layers of the protocol stack); and for users interested in the networking aspects (higher layers of the protocol stack) * Presents approaches to alleviate the challenges faced by the engineers in the field today * Furnished throughout with illustrations and case studies to clarify the notional and architectural approaches * Includes a list of problems for each chapter to emphasize the important aspects of the topics covered * Covers the current state of tactical networking as well as the future long term evolution of tactical wireless communications and networking in the next 50 years * Written at an advanced level with scope as a reference tool for engineers and scientists as well as a graduate text for advanced courses
Produktdetails
- Produktdetails
- Verlag: John Wiley & Sons
- Seitenzahl: 328
- Erscheinungstermin: 14. September 2012
- Englisch
- ISBN-13: 9781118446010
- Artikelnr.: 37348972
- Verlag: John Wiley & Sons
- Seitenzahl: 328
- Erscheinungstermin: 14. September 2012
- Englisch
- ISBN-13: 9781118446010
- Artikelnr.: 37348972
George F. Elmasry, Senior Vice President, DSCI, USA With seventeen years of industry experience, two years of college teaching experience and having published over 50 peer reviewed publications and patents, George F. Elmasry has a strong interdisciplinary background in electrical and computer engineering, computer science, research, presentation, patent, publication and grant-proposal activities. He has in-depth knowledge of commercial and tactical telecommunication systems, with an industrial background including: heading Networking and Communications Division at a US defense firm; serving as the technical lead of a wireless networking simulation and modeling group; and developing simulation software using OPNET, MS Visual C++, C under SunOS. George Elmasry obtained his PhD in Electrical Engineering from New Jersey Institute of Technology and has research publications that span from physical layer to QoS, to Network Management, to protocols and algorithms.
About the Author xi Foreword xiii Preface xv List of Acronyms xvii Part I
THEORETICAL BASIS 1 Introduction 3 1.1 The OSI Model 4 1.2 From Network
Layer to IP Layer 6 1.3 Pitfall of the OSI Model 7 1.4 Tactical Networks
Layers 9 1.5 Historical Perspective 10 Bibliography 11 2 The Physical Layer
13 2.1 Modulation 13 2.1.1 Signal-in-Space (SiS) 16 2.2 Signal Detection 22
2.2.1 Signal Detection in Two-Dimensional Space 24 2.2.2 Multidimensional
Constellations for AWGN 28 2.3 Non-Coherent Demodulation 29 2.4 Signal
Fading 29 2.5 Power Spectrum 31 2.6 Spread Spectrum Modulation 34 2.6.1
Direct Sequence Spread Spectrum 35 2.6.2 Frequency Hopping Spread Spectrum
38 2.7 Concluding Remarks 40 2.7.1 What Happens Before Modulation and After
Demodulation? 40 2.7.2 Historical Perspective 40 Bibliography 41 3 The DLL
and Information Theory in Tactical Networks 43 3.1 Information Theory and
Channel Capacity 43 3.1.1 Uncertainty and Information 45 3.1.2 Entropy 46
3.1.3 Coding for a Discrete Memoryless Source 48 3.1.4 Mutual Information
and Discrete Channels 50 3.1.5 The Binary Symmetric Channel (BSC) Model 53
3.1.6 Capacity of a Discrete Channel 54 3.2 Channel Coding, Error
Detection, and Error Correction 57 3.2.1 Hamming Distance and Probability
of Bit Error in Channel Coding 58 3.2.2 Overview of Linear Block Codes 60
3.2.3 Convolutional Codes 62 3.2.4 Concatenated Coding and Interleaving 64
3.2.5 Network Coding versus Transport Layer Packet Erasure Coding 65 3.3
Concluding Remarks 67 3.3.1 The Role of Information Theory and Coding in
Tactical Wireless Communications and Networking 67 3.3.2 Historical
Perspective 68 Appendix 3.A: Using RS Code in Tactical Networks Transport
Layer 69 3.A.1 The Utilized RS Code 69 3.A.2 Packet Erasure Analysis 70
3.A.3 Imposed Tactical Requirements 77 Bibliography 80 4 MAC and Network
Layers in Tactical Networks 83 4.1 MAC Layer and Multiple Access Techniques
83 4.2 Queuing Theory 87 4.2.1 Statistical Multiplexing of Packets 87 4.2.2
Queuing Models 92 4.3 Concluding Remarks 106 4.3.1 How Congestion Happens
in Tactical Wireless Networks 106 4.3.2 Historical Perspective 107 4.3.3
Remarks Regarding the First Part of the Book 108 Bibliography 110 Part II
THE EVOLUTION OF TACTICAL RADIOS 5 Non-IP Tactical Radios and the Move
toward IP 113 5.1 Multistep Evolution to the Global Information Grid 113
5.2 Link-16 Waveform 114 5.2.1 Link-16 Messages 119 5.2.2 Link Layer
Operations of Link-16 120 5.2.3 JTIDS/LINK-16 Modulation and Coding 120
5.2.4 Enhancements to Link-16 126 5.2.5 Concluding Remarks on Link-16
Waveform 129 5.3 EPLRS Waveform 130 5.4 SINCGARS Waveform 131 5.5 Tactical
Internet (TI) 131 5.6 IP Gateways 136 5.6.1 Throughput Efficiency 136 5.6.2
End-to-End Packet Loss 137 5.7 Concluding Remarks 137 5.7.1 What Comes
after the GIG? 137 5.7.2 Historical Perspective 137 Bibliography 138 6
IP-Based Tactical Waveforms and the GIG 141 6.1 Tactical GIG Notional
Architecture 141 6.2 Tactical GIG Waveforms 144 6.2.1 Wide-Area Network
Waveform (WNW) 144 6.2.2 Soldier Radio Waveform (SRW) 163 6.2.3 High-Band
Networking Waveform (HNW) 164 6.2.4 Network Centric Waveform (NCW) 165 6.3
The Role of Commercial Satellite in the Tactical GIG 166 6.4 Satellite
Delay Analysis 166 6.5 Networking at the Tactical GIG 169 6.6 Historical
Perspective 170 Bibliography 173 7 Cognitive Radios 177 7.1 Cognitive
Radios and Spectrum Regulations 177 7.2 Conceptualizing Cognitive Radios
180 7.2.1 Cognitive Radio Setting (CRS) Parameters 180 7.2.2 The Cognitive
Engine 181 7.3 Cognitive Radios in Tactical Environments 183 7.4 Software
Communications Architecture (SCA) 184 7.4.1 The SCA Core Framework 185
7.4.2 SCA Definitions 185 7.4.3 SCA Components 186 7.4.4 SCA and Security
Architecture 188 7.5 Spectrum Sensing 190 7.5.1 Multidimensional Spectrum
Awareness 190 7.5.2 Complexity of Spectrum Sensing 193 7.5.3 Implementation
of Spectrum Sensing 195 7.5.4 Cooperative Spectrum Sensing 199 7.5.5
Spectrum Sensing in Current Wireless Standards 200 7.6 Security in
Cognitive Radios 201 7.7 Concluding Remarks 201 7.7.1 Development of
Cognitive Radios 201 7.7.2 Modeling and Simulation of Cognitive Radios 202
7.7.3 Historical Perspective 202 Bibliography 202 Part III THE OPEN
ARCHITECTURE MODEL 8 Open Architecture in Tactical Networks 207 8.1
Commercial Cellular Wireless Open Architecture Model 208 8.2 Tactical
Wireless Open Architecture Model 210 8.3 Open Architecture Tactical
Protocol Stack Model 211 8.3.1 Tactical Wireless Open Architecture Model
Entities 213 8.3.2 Open Architecture Tactical Wireless Model ICDs 216 8.4
The Tactical Edge 219 8.4.1 Tactical Edge Definition 219 8.4.2 Tactical
Edge Analysis 220 8.5 Historical Perspective 222 Bibliography 224 9 Open
Architecture Details 225 9.1 The Plain Text IP Layer and the Tactical Edge
225 9.2 Measurement Based Resource Management 227 9.2.1 Advantages and
Challenges of MBRM 228 9.2.2 Congestion Severity Level 229 9.2.3 Markov
Chain Representation of MBAC 231 9.2.4 Regulating the Flow of Traffic
between Two Nodes 233 9.2.5 Regulating the Flow of Traffic for Multiple
Nodes 233 9.2.6 Packet Loss from the Physical Layer 234 9.3 ICD I: Plain
Text IP Layer to HAIPE 238 9.4 ICD V: Plain Text IP Layer Peer-to-Peer 239
9.4.1 TCP Proxy over HAIPE 239 9.4.2 VoIP Proxy over HAIPE 241 9.4.3 Video
Proxy over HAIPE 247 9.4.4 RSVP Proxy over HAIPE 248 9.4.5 Multicast Proxy
over HAIPE 252 9.5 ICD X Cross Layer Signaling across the HAIPE 255 9.6
Concluding Remarks 258 9.7 Historical Perspective 258 Bibliography 259 10
Bringing Commercial Cellular Capabilities to Tactical Networks 261 10.1
Tactical User Expectations 262 10.2 3G/4G/LTE Technologies within the War
Theater 264 10.3 The Tactical Cellular Gateway 265 10.4 Deployment Use
Cases 267 10.4.1 Use Case I: Smartphone Tethered to a Soldier Radio
Waveform (SRW) Radio 268 10.4.2 Use Case II: 3G/4G/LTE Services on a
Dismounted Unit 269 10.4.3 Use Case III: 3G/4G/LTE Access at an Enclave 271
10.5 Concluding Remarks 272 Bibliography 273 11 Network Management
Challenges in Tactical Networks 275 11.1 Use of Policy Based Network
Management and Gaming Theory in Tactical Networks 275 11.2 Challenges
Facing Joint Forces Interoperability 277 11.3 Joint Network Management
Architectural Approach 277 11.3.1 Assumptions and Concepts for Operations
(ConOps) 279 11.3.2 The Role of Gateway Nodes 281 11.3.3 Abstracting
Information 282 11.3.4 Creating Path Information 283 11.3.5 Sequence
Diagram 285 11.4 Conflict Resolution for Shared Resources 286 11.4.1
Tactical Network Hierarchy 287 11.4.2 Dynamic Activation of NCW in
WNW/NCW-Capable Nodes 287 11.4.3 Interfacing between the WIN-NM and the
JWNM for NCW Resources 288 11.4.4 NCW Resource Attributes 289 11.5
Concluding Remarks 290 Bibliography 291 Index 293
THEORETICAL BASIS 1 Introduction 3 1.1 The OSI Model 4 1.2 From Network
Layer to IP Layer 6 1.3 Pitfall of the OSI Model 7 1.4 Tactical Networks
Layers 9 1.5 Historical Perspective 10 Bibliography 11 2 The Physical Layer
13 2.1 Modulation 13 2.1.1 Signal-in-Space (SiS) 16 2.2 Signal Detection 22
2.2.1 Signal Detection in Two-Dimensional Space 24 2.2.2 Multidimensional
Constellations for AWGN 28 2.3 Non-Coherent Demodulation 29 2.4 Signal
Fading 29 2.5 Power Spectrum 31 2.6 Spread Spectrum Modulation 34 2.6.1
Direct Sequence Spread Spectrum 35 2.6.2 Frequency Hopping Spread Spectrum
38 2.7 Concluding Remarks 40 2.7.1 What Happens Before Modulation and After
Demodulation? 40 2.7.2 Historical Perspective 40 Bibliography 41 3 The DLL
and Information Theory in Tactical Networks 43 3.1 Information Theory and
Channel Capacity 43 3.1.1 Uncertainty and Information 45 3.1.2 Entropy 46
3.1.3 Coding for a Discrete Memoryless Source 48 3.1.4 Mutual Information
and Discrete Channels 50 3.1.5 The Binary Symmetric Channel (BSC) Model 53
3.1.6 Capacity of a Discrete Channel 54 3.2 Channel Coding, Error
Detection, and Error Correction 57 3.2.1 Hamming Distance and Probability
of Bit Error in Channel Coding 58 3.2.2 Overview of Linear Block Codes 60
3.2.3 Convolutional Codes 62 3.2.4 Concatenated Coding and Interleaving 64
3.2.5 Network Coding versus Transport Layer Packet Erasure Coding 65 3.3
Concluding Remarks 67 3.3.1 The Role of Information Theory and Coding in
Tactical Wireless Communications and Networking 67 3.3.2 Historical
Perspective 68 Appendix 3.A: Using RS Code in Tactical Networks Transport
Layer 69 3.A.1 The Utilized RS Code 69 3.A.2 Packet Erasure Analysis 70
3.A.3 Imposed Tactical Requirements 77 Bibliography 80 4 MAC and Network
Layers in Tactical Networks 83 4.1 MAC Layer and Multiple Access Techniques
83 4.2 Queuing Theory 87 4.2.1 Statistical Multiplexing of Packets 87 4.2.2
Queuing Models 92 4.3 Concluding Remarks 106 4.3.1 How Congestion Happens
in Tactical Wireless Networks 106 4.3.2 Historical Perspective 107 4.3.3
Remarks Regarding the First Part of the Book 108 Bibliography 110 Part II
THE EVOLUTION OF TACTICAL RADIOS 5 Non-IP Tactical Radios and the Move
toward IP 113 5.1 Multistep Evolution to the Global Information Grid 113
5.2 Link-16 Waveform 114 5.2.1 Link-16 Messages 119 5.2.2 Link Layer
Operations of Link-16 120 5.2.3 JTIDS/LINK-16 Modulation and Coding 120
5.2.4 Enhancements to Link-16 126 5.2.5 Concluding Remarks on Link-16
Waveform 129 5.3 EPLRS Waveform 130 5.4 SINCGARS Waveform 131 5.5 Tactical
Internet (TI) 131 5.6 IP Gateways 136 5.6.1 Throughput Efficiency 136 5.6.2
End-to-End Packet Loss 137 5.7 Concluding Remarks 137 5.7.1 What Comes
after the GIG? 137 5.7.2 Historical Perspective 137 Bibliography 138 6
IP-Based Tactical Waveforms and the GIG 141 6.1 Tactical GIG Notional
Architecture 141 6.2 Tactical GIG Waveforms 144 6.2.1 Wide-Area Network
Waveform (WNW) 144 6.2.2 Soldier Radio Waveform (SRW) 163 6.2.3 High-Band
Networking Waveform (HNW) 164 6.2.4 Network Centric Waveform (NCW) 165 6.3
The Role of Commercial Satellite in the Tactical GIG 166 6.4 Satellite
Delay Analysis 166 6.5 Networking at the Tactical GIG 169 6.6 Historical
Perspective 170 Bibliography 173 7 Cognitive Radios 177 7.1 Cognitive
Radios and Spectrum Regulations 177 7.2 Conceptualizing Cognitive Radios
180 7.2.1 Cognitive Radio Setting (CRS) Parameters 180 7.2.2 The Cognitive
Engine 181 7.3 Cognitive Radios in Tactical Environments 183 7.4 Software
Communications Architecture (SCA) 184 7.4.1 The SCA Core Framework 185
7.4.2 SCA Definitions 185 7.4.3 SCA Components 186 7.4.4 SCA and Security
Architecture 188 7.5 Spectrum Sensing 190 7.5.1 Multidimensional Spectrum
Awareness 190 7.5.2 Complexity of Spectrum Sensing 193 7.5.3 Implementation
of Spectrum Sensing 195 7.5.4 Cooperative Spectrum Sensing 199 7.5.5
Spectrum Sensing in Current Wireless Standards 200 7.6 Security in
Cognitive Radios 201 7.7 Concluding Remarks 201 7.7.1 Development of
Cognitive Radios 201 7.7.2 Modeling and Simulation of Cognitive Radios 202
7.7.3 Historical Perspective 202 Bibliography 202 Part III THE OPEN
ARCHITECTURE MODEL 8 Open Architecture in Tactical Networks 207 8.1
Commercial Cellular Wireless Open Architecture Model 208 8.2 Tactical
Wireless Open Architecture Model 210 8.3 Open Architecture Tactical
Protocol Stack Model 211 8.3.1 Tactical Wireless Open Architecture Model
Entities 213 8.3.2 Open Architecture Tactical Wireless Model ICDs 216 8.4
The Tactical Edge 219 8.4.1 Tactical Edge Definition 219 8.4.2 Tactical
Edge Analysis 220 8.5 Historical Perspective 222 Bibliography 224 9 Open
Architecture Details 225 9.1 The Plain Text IP Layer and the Tactical Edge
225 9.2 Measurement Based Resource Management 227 9.2.1 Advantages and
Challenges of MBRM 228 9.2.2 Congestion Severity Level 229 9.2.3 Markov
Chain Representation of MBAC 231 9.2.4 Regulating the Flow of Traffic
between Two Nodes 233 9.2.5 Regulating the Flow of Traffic for Multiple
Nodes 233 9.2.6 Packet Loss from the Physical Layer 234 9.3 ICD I: Plain
Text IP Layer to HAIPE 238 9.4 ICD V: Plain Text IP Layer Peer-to-Peer 239
9.4.1 TCP Proxy over HAIPE 239 9.4.2 VoIP Proxy over HAIPE 241 9.4.3 Video
Proxy over HAIPE 247 9.4.4 RSVP Proxy over HAIPE 248 9.4.5 Multicast Proxy
over HAIPE 252 9.5 ICD X Cross Layer Signaling across the HAIPE 255 9.6
Concluding Remarks 258 9.7 Historical Perspective 258 Bibliography 259 10
Bringing Commercial Cellular Capabilities to Tactical Networks 261 10.1
Tactical User Expectations 262 10.2 3G/4G/LTE Technologies within the War
Theater 264 10.3 The Tactical Cellular Gateway 265 10.4 Deployment Use
Cases 267 10.4.1 Use Case I: Smartphone Tethered to a Soldier Radio
Waveform (SRW) Radio 268 10.4.2 Use Case II: 3G/4G/LTE Services on a
Dismounted Unit 269 10.4.3 Use Case III: 3G/4G/LTE Access at an Enclave 271
10.5 Concluding Remarks 272 Bibliography 273 11 Network Management
Challenges in Tactical Networks 275 11.1 Use of Policy Based Network
Management and Gaming Theory in Tactical Networks 275 11.2 Challenges
Facing Joint Forces Interoperability 277 11.3 Joint Network Management
Architectural Approach 277 11.3.1 Assumptions and Concepts for Operations
(ConOps) 279 11.3.2 The Role of Gateway Nodes 281 11.3.3 Abstracting
Information 282 11.3.4 Creating Path Information 283 11.3.5 Sequence
Diagram 285 11.4 Conflict Resolution for Shared Resources 286 11.4.1
Tactical Network Hierarchy 287 11.4.2 Dynamic Activation of NCW in
WNW/NCW-Capable Nodes 287 11.4.3 Interfacing between the WIN-NM and the
JWNM for NCW Resources 288 11.4.4 NCW Resource Attributes 289 11.5
Concluding Remarks 290 Bibliography 291 Index 293
About the Author xi Foreword xiii Preface xv List of Acronyms xvii Part I
THEORETICAL BASIS 1 Introduction 3 1.1 The OSI Model 4 1.2 From Network
Layer to IP Layer 6 1.3 Pitfall of the OSI Model 7 1.4 Tactical Networks
Layers 9 1.5 Historical Perspective 10 Bibliography 11 2 The Physical Layer
13 2.1 Modulation 13 2.1.1 Signal-in-Space (SiS) 16 2.2 Signal Detection 22
2.2.1 Signal Detection in Two-Dimensional Space 24 2.2.2 Multidimensional
Constellations for AWGN 28 2.3 Non-Coherent Demodulation 29 2.4 Signal
Fading 29 2.5 Power Spectrum 31 2.6 Spread Spectrum Modulation 34 2.6.1
Direct Sequence Spread Spectrum 35 2.6.2 Frequency Hopping Spread Spectrum
38 2.7 Concluding Remarks 40 2.7.1 What Happens Before Modulation and After
Demodulation? 40 2.7.2 Historical Perspective 40 Bibliography 41 3 The DLL
and Information Theory in Tactical Networks 43 3.1 Information Theory and
Channel Capacity 43 3.1.1 Uncertainty and Information 45 3.1.2 Entropy 46
3.1.3 Coding for a Discrete Memoryless Source 48 3.1.4 Mutual Information
and Discrete Channels 50 3.1.5 The Binary Symmetric Channel (BSC) Model 53
3.1.6 Capacity of a Discrete Channel 54 3.2 Channel Coding, Error
Detection, and Error Correction 57 3.2.1 Hamming Distance and Probability
of Bit Error in Channel Coding 58 3.2.2 Overview of Linear Block Codes 60
3.2.3 Convolutional Codes 62 3.2.4 Concatenated Coding and Interleaving 64
3.2.5 Network Coding versus Transport Layer Packet Erasure Coding 65 3.3
Concluding Remarks 67 3.3.1 The Role of Information Theory and Coding in
Tactical Wireless Communications and Networking 67 3.3.2 Historical
Perspective 68 Appendix 3.A: Using RS Code in Tactical Networks Transport
Layer 69 3.A.1 The Utilized RS Code 69 3.A.2 Packet Erasure Analysis 70
3.A.3 Imposed Tactical Requirements 77 Bibliography 80 4 MAC and Network
Layers in Tactical Networks 83 4.1 MAC Layer and Multiple Access Techniques
83 4.2 Queuing Theory 87 4.2.1 Statistical Multiplexing of Packets 87 4.2.2
Queuing Models 92 4.3 Concluding Remarks 106 4.3.1 How Congestion Happens
in Tactical Wireless Networks 106 4.3.2 Historical Perspective 107 4.3.3
Remarks Regarding the First Part of the Book 108 Bibliography 110 Part II
THE EVOLUTION OF TACTICAL RADIOS 5 Non-IP Tactical Radios and the Move
toward IP 113 5.1 Multistep Evolution to the Global Information Grid 113
5.2 Link-16 Waveform 114 5.2.1 Link-16 Messages 119 5.2.2 Link Layer
Operations of Link-16 120 5.2.3 JTIDS/LINK-16 Modulation and Coding 120
5.2.4 Enhancements to Link-16 126 5.2.5 Concluding Remarks on Link-16
Waveform 129 5.3 EPLRS Waveform 130 5.4 SINCGARS Waveform 131 5.5 Tactical
Internet (TI) 131 5.6 IP Gateways 136 5.6.1 Throughput Efficiency 136 5.6.2
End-to-End Packet Loss 137 5.7 Concluding Remarks 137 5.7.1 What Comes
after the GIG? 137 5.7.2 Historical Perspective 137 Bibliography 138 6
IP-Based Tactical Waveforms and the GIG 141 6.1 Tactical GIG Notional
Architecture 141 6.2 Tactical GIG Waveforms 144 6.2.1 Wide-Area Network
Waveform (WNW) 144 6.2.2 Soldier Radio Waveform (SRW) 163 6.2.3 High-Band
Networking Waveform (HNW) 164 6.2.4 Network Centric Waveform (NCW) 165 6.3
The Role of Commercial Satellite in the Tactical GIG 166 6.4 Satellite
Delay Analysis 166 6.5 Networking at the Tactical GIG 169 6.6 Historical
Perspective 170 Bibliography 173 7 Cognitive Radios 177 7.1 Cognitive
Radios and Spectrum Regulations 177 7.2 Conceptualizing Cognitive Radios
180 7.2.1 Cognitive Radio Setting (CRS) Parameters 180 7.2.2 The Cognitive
Engine 181 7.3 Cognitive Radios in Tactical Environments 183 7.4 Software
Communications Architecture (SCA) 184 7.4.1 The SCA Core Framework 185
7.4.2 SCA Definitions 185 7.4.3 SCA Components 186 7.4.4 SCA and Security
Architecture 188 7.5 Spectrum Sensing 190 7.5.1 Multidimensional Spectrum
Awareness 190 7.5.2 Complexity of Spectrum Sensing 193 7.5.3 Implementation
of Spectrum Sensing 195 7.5.4 Cooperative Spectrum Sensing 199 7.5.5
Spectrum Sensing in Current Wireless Standards 200 7.6 Security in
Cognitive Radios 201 7.7 Concluding Remarks 201 7.7.1 Development of
Cognitive Radios 201 7.7.2 Modeling and Simulation of Cognitive Radios 202
7.7.3 Historical Perspective 202 Bibliography 202 Part III THE OPEN
ARCHITECTURE MODEL 8 Open Architecture in Tactical Networks 207 8.1
Commercial Cellular Wireless Open Architecture Model 208 8.2 Tactical
Wireless Open Architecture Model 210 8.3 Open Architecture Tactical
Protocol Stack Model 211 8.3.1 Tactical Wireless Open Architecture Model
Entities 213 8.3.2 Open Architecture Tactical Wireless Model ICDs 216 8.4
The Tactical Edge 219 8.4.1 Tactical Edge Definition 219 8.4.2 Tactical
Edge Analysis 220 8.5 Historical Perspective 222 Bibliography 224 9 Open
Architecture Details 225 9.1 The Plain Text IP Layer and the Tactical Edge
225 9.2 Measurement Based Resource Management 227 9.2.1 Advantages and
Challenges of MBRM 228 9.2.2 Congestion Severity Level 229 9.2.3 Markov
Chain Representation of MBAC 231 9.2.4 Regulating the Flow of Traffic
between Two Nodes 233 9.2.5 Regulating the Flow of Traffic for Multiple
Nodes 233 9.2.6 Packet Loss from the Physical Layer 234 9.3 ICD I: Plain
Text IP Layer to HAIPE 238 9.4 ICD V: Plain Text IP Layer Peer-to-Peer 239
9.4.1 TCP Proxy over HAIPE 239 9.4.2 VoIP Proxy over HAIPE 241 9.4.3 Video
Proxy over HAIPE 247 9.4.4 RSVP Proxy over HAIPE 248 9.4.5 Multicast Proxy
over HAIPE 252 9.5 ICD X Cross Layer Signaling across the HAIPE 255 9.6
Concluding Remarks 258 9.7 Historical Perspective 258 Bibliography 259 10
Bringing Commercial Cellular Capabilities to Tactical Networks 261 10.1
Tactical User Expectations 262 10.2 3G/4G/LTE Technologies within the War
Theater 264 10.3 The Tactical Cellular Gateway 265 10.4 Deployment Use
Cases 267 10.4.1 Use Case I: Smartphone Tethered to a Soldier Radio
Waveform (SRW) Radio 268 10.4.2 Use Case II: 3G/4G/LTE Services on a
Dismounted Unit 269 10.4.3 Use Case III: 3G/4G/LTE Access at an Enclave 271
10.5 Concluding Remarks 272 Bibliography 273 11 Network Management
Challenges in Tactical Networks 275 11.1 Use of Policy Based Network
Management and Gaming Theory in Tactical Networks 275 11.2 Challenges
Facing Joint Forces Interoperability 277 11.3 Joint Network Management
Architectural Approach 277 11.3.1 Assumptions and Concepts for Operations
(ConOps) 279 11.3.2 The Role of Gateway Nodes 281 11.3.3 Abstracting
Information 282 11.3.4 Creating Path Information 283 11.3.5 Sequence
Diagram 285 11.4 Conflict Resolution for Shared Resources 286 11.4.1
Tactical Network Hierarchy 287 11.4.2 Dynamic Activation of NCW in
WNW/NCW-Capable Nodes 287 11.4.3 Interfacing between the WIN-NM and the
JWNM for NCW Resources 288 11.4.4 NCW Resource Attributes 289 11.5
Concluding Remarks 290 Bibliography 291 Index 293
THEORETICAL BASIS 1 Introduction 3 1.1 The OSI Model 4 1.2 From Network
Layer to IP Layer 6 1.3 Pitfall of the OSI Model 7 1.4 Tactical Networks
Layers 9 1.5 Historical Perspective 10 Bibliography 11 2 The Physical Layer
13 2.1 Modulation 13 2.1.1 Signal-in-Space (SiS) 16 2.2 Signal Detection 22
2.2.1 Signal Detection in Two-Dimensional Space 24 2.2.2 Multidimensional
Constellations for AWGN 28 2.3 Non-Coherent Demodulation 29 2.4 Signal
Fading 29 2.5 Power Spectrum 31 2.6 Spread Spectrum Modulation 34 2.6.1
Direct Sequence Spread Spectrum 35 2.6.2 Frequency Hopping Spread Spectrum
38 2.7 Concluding Remarks 40 2.7.1 What Happens Before Modulation and After
Demodulation? 40 2.7.2 Historical Perspective 40 Bibliography 41 3 The DLL
and Information Theory in Tactical Networks 43 3.1 Information Theory and
Channel Capacity 43 3.1.1 Uncertainty and Information 45 3.1.2 Entropy 46
3.1.3 Coding for a Discrete Memoryless Source 48 3.1.4 Mutual Information
and Discrete Channels 50 3.1.5 The Binary Symmetric Channel (BSC) Model 53
3.1.6 Capacity of a Discrete Channel 54 3.2 Channel Coding, Error
Detection, and Error Correction 57 3.2.1 Hamming Distance and Probability
of Bit Error in Channel Coding 58 3.2.2 Overview of Linear Block Codes 60
3.2.3 Convolutional Codes 62 3.2.4 Concatenated Coding and Interleaving 64
3.2.5 Network Coding versus Transport Layer Packet Erasure Coding 65 3.3
Concluding Remarks 67 3.3.1 The Role of Information Theory and Coding in
Tactical Wireless Communications and Networking 67 3.3.2 Historical
Perspective 68 Appendix 3.A: Using RS Code in Tactical Networks Transport
Layer 69 3.A.1 The Utilized RS Code 69 3.A.2 Packet Erasure Analysis 70
3.A.3 Imposed Tactical Requirements 77 Bibliography 80 4 MAC and Network
Layers in Tactical Networks 83 4.1 MAC Layer and Multiple Access Techniques
83 4.2 Queuing Theory 87 4.2.1 Statistical Multiplexing of Packets 87 4.2.2
Queuing Models 92 4.3 Concluding Remarks 106 4.3.1 How Congestion Happens
in Tactical Wireless Networks 106 4.3.2 Historical Perspective 107 4.3.3
Remarks Regarding the First Part of the Book 108 Bibliography 110 Part II
THE EVOLUTION OF TACTICAL RADIOS 5 Non-IP Tactical Radios and the Move
toward IP 113 5.1 Multistep Evolution to the Global Information Grid 113
5.2 Link-16 Waveform 114 5.2.1 Link-16 Messages 119 5.2.2 Link Layer
Operations of Link-16 120 5.2.3 JTIDS/LINK-16 Modulation and Coding 120
5.2.4 Enhancements to Link-16 126 5.2.5 Concluding Remarks on Link-16
Waveform 129 5.3 EPLRS Waveform 130 5.4 SINCGARS Waveform 131 5.5 Tactical
Internet (TI) 131 5.6 IP Gateways 136 5.6.1 Throughput Efficiency 136 5.6.2
End-to-End Packet Loss 137 5.7 Concluding Remarks 137 5.7.1 What Comes
after the GIG? 137 5.7.2 Historical Perspective 137 Bibliography 138 6
IP-Based Tactical Waveforms and the GIG 141 6.1 Tactical GIG Notional
Architecture 141 6.2 Tactical GIG Waveforms 144 6.2.1 Wide-Area Network
Waveform (WNW) 144 6.2.2 Soldier Radio Waveform (SRW) 163 6.2.3 High-Band
Networking Waveform (HNW) 164 6.2.4 Network Centric Waveform (NCW) 165 6.3
The Role of Commercial Satellite in the Tactical GIG 166 6.4 Satellite
Delay Analysis 166 6.5 Networking at the Tactical GIG 169 6.6 Historical
Perspective 170 Bibliography 173 7 Cognitive Radios 177 7.1 Cognitive
Radios and Spectrum Regulations 177 7.2 Conceptualizing Cognitive Radios
180 7.2.1 Cognitive Radio Setting (CRS) Parameters 180 7.2.2 The Cognitive
Engine 181 7.3 Cognitive Radios in Tactical Environments 183 7.4 Software
Communications Architecture (SCA) 184 7.4.1 The SCA Core Framework 185
7.4.2 SCA Definitions 185 7.4.3 SCA Components 186 7.4.4 SCA and Security
Architecture 188 7.5 Spectrum Sensing 190 7.5.1 Multidimensional Spectrum
Awareness 190 7.5.2 Complexity of Spectrum Sensing 193 7.5.3 Implementation
of Spectrum Sensing 195 7.5.4 Cooperative Spectrum Sensing 199 7.5.5
Spectrum Sensing in Current Wireless Standards 200 7.6 Security in
Cognitive Radios 201 7.7 Concluding Remarks 201 7.7.1 Development of
Cognitive Radios 201 7.7.2 Modeling and Simulation of Cognitive Radios 202
7.7.3 Historical Perspective 202 Bibliography 202 Part III THE OPEN
ARCHITECTURE MODEL 8 Open Architecture in Tactical Networks 207 8.1
Commercial Cellular Wireless Open Architecture Model 208 8.2 Tactical
Wireless Open Architecture Model 210 8.3 Open Architecture Tactical
Protocol Stack Model 211 8.3.1 Tactical Wireless Open Architecture Model
Entities 213 8.3.2 Open Architecture Tactical Wireless Model ICDs 216 8.4
The Tactical Edge 219 8.4.1 Tactical Edge Definition 219 8.4.2 Tactical
Edge Analysis 220 8.5 Historical Perspective 222 Bibliography 224 9 Open
Architecture Details 225 9.1 The Plain Text IP Layer and the Tactical Edge
225 9.2 Measurement Based Resource Management 227 9.2.1 Advantages and
Challenges of MBRM 228 9.2.2 Congestion Severity Level 229 9.2.3 Markov
Chain Representation of MBAC 231 9.2.4 Regulating the Flow of Traffic
between Two Nodes 233 9.2.5 Regulating the Flow of Traffic for Multiple
Nodes 233 9.2.6 Packet Loss from the Physical Layer 234 9.3 ICD I: Plain
Text IP Layer to HAIPE 238 9.4 ICD V: Plain Text IP Layer Peer-to-Peer 239
9.4.1 TCP Proxy over HAIPE 239 9.4.2 VoIP Proxy over HAIPE 241 9.4.3 Video
Proxy over HAIPE 247 9.4.4 RSVP Proxy over HAIPE 248 9.4.5 Multicast Proxy
over HAIPE 252 9.5 ICD X Cross Layer Signaling across the HAIPE 255 9.6
Concluding Remarks 258 9.7 Historical Perspective 258 Bibliography 259 10
Bringing Commercial Cellular Capabilities to Tactical Networks 261 10.1
Tactical User Expectations 262 10.2 3G/4G/LTE Technologies within the War
Theater 264 10.3 The Tactical Cellular Gateway 265 10.4 Deployment Use
Cases 267 10.4.1 Use Case I: Smartphone Tethered to a Soldier Radio
Waveform (SRW) Radio 268 10.4.2 Use Case II: 3G/4G/LTE Services on a
Dismounted Unit 269 10.4.3 Use Case III: 3G/4G/LTE Access at an Enclave 271
10.5 Concluding Remarks 272 Bibliography 273 11 Network Management
Challenges in Tactical Networks 275 11.1 Use of Policy Based Network
Management and Gaming Theory in Tactical Networks 275 11.2 Challenges
Facing Joint Forces Interoperability 277 11.3 Joint Network Management
Architectural Approach 277 11.3.1 Assumptions and Concepts for Operations
(ConOps) 279 11.3.2 The Role of Gateway Nodes 281 11.3.3 Abstracting
Information 282 11.3.4 Creating Path Information 283 11.3.5 Sequence
Diagram 285 11.4 Conflict Resolution for Shared Resources 286 11.4.1
Tactical Network Hierarchy 287 11.4.2 Dynamic Activation of NCW in
WNW/NCW-Capable Nodes 287 11.4.3 Interfacing between the WIN-NM and the
JWNM for NCW Resources 288 11.4.4 NCW Resource Attributes 289 11.5
Concluding Remarks 290 Bibliography 291 Index 293