Info
- Utilizzare la checkbox di selezione a fianco di ciascun documento per attivare le funzionalità di stampa, invio email, download nei formati disponibili del (i) record.
3g, 4g and beyond : bringing networks, devices, and the web together / / Martin Sauter
| 3g, 4g and beyond : bringing networks, devices, and the web together / / Martin Sauter |
| Autore | Sauter Martin |
| Edizione | [2nd ed.] |
| Pubbl/distr/stampa | Chichester, West Sussex, UK : , : Wiley/A John Wiley and Sons, Ltd., Publication, , 2013 |
| Descrizione fisica | 1 online resource (379 p.) |
| Disciplina | 384.5 |
| Soggetto topico |
Wireless Internet
Wireless communication systems Mobile communication systems Smartphones Mobile computing Long-Term Evolution (Telecommunications) |
| ISBN |
1-118-39454-2
1-299-18850-8 1-118-39456-9 1-118-39453-4 |
| Formato | Materiale a stampa  |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Nota di contenuto |
-- Preface xi -- 1 Evolution from 2G over 3G to 4G 1 -- 1.1 First Half of the 1990s - Voice-Centric Communication 1 -- 1.2 Between 1995 and 2000: The Rise of Mobility and the Internet 1 -- 1.3 Between 2000 and 2005: Dot Com Burst, Web 2.0, Mobile Internet 2 -- 1.4 Between 2005 and 2010: Global Coverage, Fixed Line VoIP, and Mobile Broadband 4 -- 1.5 2010 and Beyond 5 -- 1.6 All over IP in Mobile - The Biggest Challenge 6 -- 1.7 Summary 6 -- 2 Beyond 3G Network Architectures 9 -- 2.1 Overview 9 -- 2.2 UMTS, HSPA, and HSPA+ 10 -- 2.3 LTE 43 -- 2.4 802.11 Wi-Fi 74 -- 3 Network Capacity and Usage Scenarios 95 -- 3.1 Usage in Developed Markets and Emerging Economies 95 -- 3.2 How to Control Mobile Usage 96 -- 3.3 Measuring Mobile Usage from a Financial Point of View 99 -- 3.4 Cell Capacity in Downlink 100 -- 3.5 Current and Future Frequency Bands for Cellular Wireless 105 -- 3.6 Cell Capacity in Uplink 106 -- 3.7 Per-User Throughput in Downlink 109 -- 3.8 Per-User Throughput in Uplink 114 -- 3.9 Traffic Estimation Per User 116 -- 3.10 Overall Wireless Network Capacity 117 -- 3.11 Network Capacity for Train Routes, Highways, and Remote Areas 124 -- 3.12 When will GSM be Switched Off? 125 -- 3.13 Cellular Network VoIP Capacity 127 -- 3.14 Wi-Fi VoIP Capacity 130 -- 3.15 Wi-Fi and Interference 132 -- 3.16 Wi-Fi Capacity in Combination with DSL, Cable, and Fiber 134 -- 3.17 Backhaul for Wireless Networks 138 -- 3.18 A Hybrid Cellular/Wi-Fi Network Today and in the Future 143 -- 4 Voice over Wireless 149 -- 4.1 Circuit-Switched Mobile Voice Telephony 150 -- 4.2 Packet-Switched Voice Telephony 153 -- 4.3 SIP Telephony over Fixed and Wireless Networks 157 -- 4.4 Voice and Related Applications over IMS 169 -- 4.5 Voice over DSL and Cable with Femtocells 223 -- 4.6 Unlicensed Mobile Access and Generic Access Network 228 -- 4.7 Network Operator Deployed Voice over IP Alternatives 231 -- 4.8 Over-the-Top (OTT) Voice over IP Alternatives 236 -- 4.9 Which Voice Technology will Reign in the Future? 237.
5 Evolution of Mobile Devices and Operating Systems 241 -- 5.1 Introduction 241 -- 5.2 The System Architecture for Voice-Optimized Devices 246 -- 5.3 The System Architecture for Multimedia Devices 248 -- 5.4 Mobile Graphics Acceleration 253 -- 5.5 Hardware Evolution 256 -- 5.6 Multimode, Multifrequency Terminals 273 -- 5.7 Wireless Notebook Connectivity 276 -- 5.8 Impact of Hardware Evolution on Future Data Traffic 277 -- 5.9 Power Consumption and User Interface as the Dividing Line in Mobile Device Evolution 279 -- 5.10 Feature Phone Operating Systems 280 -- 5.11 Smartphone Operating Systems 282 -- 5.12 Operating System Tasks 288 -- 6 Mobile Web 2.0, Apps, and Owners 297 -- 6.1 Overview 297 -- 6.2 (Mobile) Web 1.0 - How Everything Started 298 -- 6.3 Web 2.0 - Empowering the User 299 -- 6.4 Web 2.0 from the User's Point of View 299 -- 6.5 The Ideas behind Web 2.0 306 -- 6.6 Discovering the Fabrics of Web 2.0 310 -- 6.7 Mobile Web 2.0 - Evolution and Revolution of Web 2.0 321 -- 6.8 (Mobile) Web 2.0 and Privacy and Security Considerations 334 -- 6.9 Mobile Apps 340 -- 6.10 Android App Programing Introduction 342 -- 6.11 Impact of Mobile Apps on Networks and Power Consumption 349 -- 6.12 Mobile Apps Security and Privacy Considerations 351 -- 6.13 Summary 354 -- 7 Conclusion 357 -- Index 361. |
| Altri titoli varianti | Three g, four g and beyond |
| Record Nr. | UNINA-9910141478203321 |
Sauter Martin
|
||
| Chichester, West Sussex, UK : , : Wiley/A John Wiley and Sons, Ltd., Publication, , 2013 | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
| ||
3g, 4g and beyond : bringing networks, devices, and the web together / / Martin Sauter
| 3g, 4g and beyond : bringing networks, devices, and the web together / / Martin Sauter |
| Autore | Sauter Martin |
| Edizione | [2nd ed.] |
| Pubbl/distr/stampa | Chichester, West Sussex, UK : , : Wiley/A John Wiley and Sons, Ltd., Publication, , 2013 |
| Descrizione fisica | 1 online resource (379 p.) |
| Disciplina | 384.5 |
| Soggetto topico |
Wireless Internet
Wireless communication systems Mobile communication systems Smartphones Mobile computing Long-Term Evolution (Telecommunications) |
| ISBN |
1-118-39454-2
1-299-18850-8 1-118-39456-9 1-118-39453-4 |
| Formato | Materiale a stampa |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Nota di contenuto |
-- Preface xi -- 1 Evolution from 2G over 3G to 4G 1 -- 1.1 First Half of the 1990s - Voice-Centric Communication 1 -- 1.2 Between 1995 and 2000: The Rise of Mobility and the Internet 1 -- 1.3 Between 2000 and 2005: Dot Com Burst, Web 2.0, Mobile Internet 2 -- 1.4 Between 2005 and 2010: Global Coverage, Fixed Line VoIP, and Mobile Broadband 4 -- 1.5 2010 and Beyond 5 -- 1.6 All over IP in Mobile - The Biggest Challenge 6 -- 1.7 Summary 6 -- 2 Beyond 3G Network Architectures 9 -- 2.1 Overview 9 -- 2.2 UMTS, HSPA, and HSPA+ 10 -- 2.3 LTE 43 -- 2.4 802.11 Wi-Fi 74 -- 3 Network Capacity and Usage Scenarios 95 -- 3.1 Usage in Developed Markets and Emerging Economies 95 -- 3.2 How to Control Mobile Usage 96 -- 3.3 Measuring Mobile Usage from a Financial Point of View 99 -- 3.4 Cell Capacity in Downlink 100 -- 3.5 Current and Future Frequency Bands for Cellular Wireless 105 -- 3.6 Cell Capacity in Uplink 106 -- 3.7 Per-User Throughput in Downlink 109 -- 3.8 Per-User Throughput in Uplink 114 -- 3.9 Traffic Estimation Per User 116 -- 3.10 Overall Wireless Network Capacity 117 -- 3.11 Network Capacity for Train Routes, Highways, and Remote Areas 124 -- 3.12 When will GSM be Switched Off? 125 -- 3.13 Cellular Network VoIP Capacity 127 -- 3.14 Wi-Fi VoIP Capacity 130 -- 3.15 Wi-Fi and Interference 132 -- 3.16 Wi-Fi Capacity in Combination with DSL, Cable, and Fiber 134 -- 3.17 Backhaul for Wireless Networks 138 -- 3.18 A Hybrid Cellular/Wi-Fi Network Today and in the Future 143 -- 4 Voice over Wireless 149 -- 4.1 Circuit-Switched Mobile Voice Telephony 150 -- 4.2 Packet-Switched Voice Telephony 153 -- 4.3 SIP Telephony over Fixed and Wireless Networks 157 -- 4.4 Voice and Related Applications over IMS 169 -- 4.5 Voice over DSL and Cable with Femtocells 223 -- 4.6 Unlicensed Mobile Access and Generic Access Network 228 -- 4.7 Network Operator Deployed Voice over IP Alternatives 231 -- 4.8 Over-the-Top (OTT) Voice over IP Alternatives 236 -- 4.9 Which Voice Technology will Reign in the Future? 237.
5 Evolution of Mobile Devices and Operating Systems 241 -- 5.1 Introduction 241 -- 5.2 The System Architecture for Voice-Optimized Devices 246 -- 5.3 The System Architecture for Multimedia Devices 248 -- 5.4 Mobile Graphics Acceleration 253 -- 5.5 Hardware Evolution 256 -- 5.6 Multimode, Multifrequency Terminals 273 -- 5.7 Wireless Notebook Connectivity 276 -- 5.8 Impact of Hardware Evolution on Future Data Traffic 277 -- 5.9 Power Consumption and User Interface as the Dividing Line in Mobile Device Evolution 279 -- 5.10 Feature Phone Operating Systems 280 -- 5.11 Smartphone Operating Systems 282 -- 5.12 Operating System Tasks 288 -- 6 Mobile Web 2.0, Apps, and Owners 297 -- 6.1 Overview 297 -- 6.2 (Mobile) Web 1.0 - How Everything Started 298 -- 6.3 Web 2.0 - Empowering the User 299 -- 6.4 Web 2.0 from the User's Point of View 299 -- 6.5 The Ideas behind Web 2.0 306 -- 6.6 Discovering the Fabrics of Web 2.0 310 -- 6.7 Mobile Web 2.0 - Evolution and Revolution of Web 2.0 321 -- 6.8 (Mobile) Web 2.0 and Privacy and Security Considerations 334 -- 6.9 Mobile Apps 340 -- 6.10 Android App Programing Introduction 342 -- 6.11 Impact of Mobile Apps on Networks and Power Consumption 349 -- 6.12 Mobile Apps Security and Privacy Considerations 351 -- 6.13 Summary 354 -- 7 Conclusion 357 -- Index 361. |
| Altri titoli varianti | Three g, four g and beyond |
| Record Nr. | UNINA-9910817050503321 |
|
Sauter Martin
|
||
| Chichester, West Sussex, UK : , : Wiley/A John Wiley and Sons, Ltd., Publication, , 2013 | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
| ||
4G LTE/LTE-advanced for mobile broadband [[electronic resource] /] / Erik Dahlman, Stefan Parkvall, and Johan Sköld
| 4G LTE/LTE-advanced for mobile broadband [[electronic resource] /] / Erik Dahlman, Stefan Parkvall, and Johan Sköld |
| Autore | Dahlman Erik |
| Edizione | [1st edition] |
| Pubbl/distr/stampa | Oxford [U.K.] ; ; Burlington, Mass., : Academic Press, an imprint of Elsevier, 2011 |
| Descrizione fisica | 1 online resource (456 p.) |
| Disciplina |
384.5
621.38456 |
| Altri autori (Persone) |
ParkvallStefan
SköldJohan |
| Soggetto topico |
Long-Term Evolution (Telecommunications)
Broadband communication systems Mobile communication systems |
| Soggetto genere / forma | Electronic books. |
| ISBN |
1-283-17124-4
9786613171245 0-12-385490-3 |
| Formato | Materiale a stampa |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Nota di contenuto |
Front Cover; 4G LTE/LTE-Advanced for Mobile Broadband; Copyright Page; Contents; Preface; Acknowledgements; Abbreviations and Acronyms; CHAPTER 1 Background of LTE; 1.1 Introduction; 1.2 Evolution of Mobile Systems Before LTE; 1.3 ITU Activities; 1.4 Drivers for LTE; 1.5 Standardization of LTE; CHAPTER 2 High Data Rates in Mobile Communication; 2.1 High Data Rates: Fundamental Constraints; 2.2 Higher Data Rates Within a Limited Bandwidth: Higher-Order Modulation; 2.3 Wider Bandwidth Including Multi-Carrier Transmission; CHAPTER 3 OFDM Transmission; 3.1 Basic Principles of OFDM
3.2 OFDM Demodulation3.3 OFDM Implementation Using IFFT/FFT Processing; 3.4 Cyclic-Prefix Insertion; 3.5 Frequency-Domain Model of OFDM Transmission; 3.6 Channel Estimation and Reference Symbols; 3.7 Frequency Diversity with OFDM: Importance of Channel Coding; 3.8 Selection of Basic OFDM Parameters; 3.9 Variations in Instantaneous Transmission Power; 3.10 OFDM as a User-Multiplexing and Multiple-Access Scheme; 3.11 Multi-Cell Broadcast/Multicast Transmission and OFDM; CHAPTER 4 Wider-Band ""Single-Carrier"" Transmission; 4.1 Equalization Against Radio-Channel Frequency Selectivity 4.2 Uplink FDMA with Flexible Bandwidth Assignment4.3 DFT-Spread OFDM; CHAPTER 5 Multi-Antenna Techniques; 5.1 Multi-Antenna Configurations; 5.2 Benefits of Multi-Antenna Techniques; 5.3 Multiple Receive Antennas; 5.4 Multiple Transmit Antennas; 5.5 Spatial Multiplexing; CHAPTER 6 Scheduling, Link Adaptation, and Hybrid ARQ; 6.1 Link Adaptation: Power and Rate Control; 6.2 Channel-Dependent Scheduling; 6.3 Advanced Retransmission Schemes; 6.4 Hybrid ARQ with Soft Combining; CHAPTER 7 LTE Radio Access: An Overview; 7.1 Basic Principles; 7.2 LTE Release 9; 7.3 LTE Release 10 and IMT-Advanced 7.4 Terminal CapabilitiesCHAPTER 8 Radio-Interface Architecture; 8.1 Overall System Architecture; 8.2 Radio Protocol Architecture; 8.3 Control-Plane Protocols; CHAPTER 9 Physical Transmission Resources; 9.1 Overall Time-Frequency Structure; 9.2 Normal Subframes and MBSFN Subframes; 9.3 Carrier Aggregation; 9.4 Frequency-Domain Location of LTE Carriers; 9.5 Duplex Schemes; CHAPTER 10 Downlink Physical-Layer Processing; 10.1 Transport-Channel Processing; 10.2 Downlink Reference Signals; 10.3 Multi-Antenna Transmission; 10.4 Downlink L1/L2 Control Signaling CHAPTER 11 Uplink Physical-Layer Processing11.1 Transport-Channel Processing; 11.2 Uplink Reference Signals; 11.3 Uplink Multi-Antenna Transmission; 11.4 Uplink L1/L2 Control Signaling; 11.5 Uplink Timing Alignment; CHAPTER 12 Retransmission Protocols; 12.1 Hybrid ARQ with Soft Combining; 12.2 Radio-Link Control; CHAPTER 13 Power Control, Scheduling, and Interference Handling; 13.1 Uplink Power Control; 13.2 Scheduling and Rate Adaptation; 13.3 Inter-Cell Interference Coordination; 13.4 Heterogeneous Network Deployments; CHAPTER 14 Access Procedures; 14.1 Acquisition and Cell Search 14.2 System Information |
| Record Nr. | UNINA-9910459569703321 |
|
Dahlman Erik
|
||
| Oxford [U.K.] ; ; Burlington, Mass., : Academic Press, an imprint of Elsevier, 2011 | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
| ||
4G LTE/LTE-advanced for mobile broadband [[electronic resource] /] / Erik Dahlman, Stefan Parkvall, and Johan Sköld
| 4G LTE/LTE-advanced for mobile broadband [[electronic resource] /] / Erik Dahlman, Stefan Parkvall, and Johan Sköld |
| Autore | Dahlman Erik |
| Edizione | [1st edition] |
| Pubbl/distr/stampa | Oxford [U.K.] ; ; Burlington, Mass., : Academic Press, an imprint of Elsevier, 2011 |
| Descrizione fisica | 1 online resource (456 p.) |
| Disciplina |
384.5
621.38456 |
| Altri autori (Persone) |
ParkvallStefan
SköldJohan |
| Soggetto topico |
Long-Term Evolution (Telecommunications)
Broadband communication systems Mobile communication systems |
| ISBN |
1-283-17124-4
9786613171245 0-12-385490-3 |
| Formato | Materiale a stampa |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Nota di contenuto |
Front Cover; 4G LTE/LTE-Advanced for Mobile Broadband; Copyright Page; Contents; Preface; Acknowledgements; Abbreviations and Acronyms; CHAPTER 1 Background of LTE; 1.1 Introduction; 1.2 Evolution of Mobile Systems Before LTE; 1.3 ITU Activities; 1.4 Drivers for LTE; 1.5 Standardization of LTE; CHAPTER 2 High Data Rates in Mobile Communication; 2.1 High Data Rates: Fundamental Constraints; 2.2 Higher Data Rates Within a Limited Bandwidth: Higher-Order Modulation; 2.3 Wider Bandwidth Including Multi-Carrier Transmission; CHAPTER 3 OFDM Transmission; 3.1 Basic Principles of OFDM
3.2 OFDM Demodulation3.3 OFDM Implementation Using IFFT/FFT Processing; 3.4 Cyclic-Prefix Insertion; 3.5 Frequency-Domain Model of OFDM Transmission; 3.6 Channel Estimation and Reference Symbols; 3.7 Frequency Diversity with OFDM: Importance of Channel Coding; 3.8 Selection of Basic OFDM Parameters; 3.9 Variations in Instantaneous Transmission Power; 3.10 OFDM as a User-Multiplexing and Multiple-Access Scheme; 3.11 Multi-Cell Broadcast/Multicast Transmission and OFDM; CHAPTER 4 Wider-Band ""Single-Carrier"" Transmission; 4.1 Equalization Against Radio-Channel Frequency Selectivity 4.2 Uplink FDMA with Flexible Bandwidth Assignment4.3 DFT-Spread OFDM; CHAPTER 5 Multi-Antenna Techniques; 5.1 Multi-Antenna Configurations; 5.2 Benefits of Multi-Antenna Techniques; 5.3 Multiple Receive Antennas; 5.4 Multiple Transmit Antennas; 5.5 Spatial Multiplexing; CHAPTER 6 Scheduling, Link Adaptation, and Hybrid ARQ; 6.1 Link Adaptation: Power and Rate Control; 6.2 Channel-Dependent Scheduling; 6.3 Advanced Retransmission Schemes; 6.4 Hybrid ARQ with Soft Combining; CHAPTER 7 LTE Radio Access: An Overview; 7.1 Basic Principles; 7.2 LTE Release 9; 7.3 LTE Release 10 and IMT-Advanced 7.4 Terminal CapabilitiesCHAPTER 8 Radio-Interface Architecture; 8.1 Overall System Architecture; 8.2 Radio Protocol Architecture; 8.3 Control-Plane Protocols; CHAPTER 9 Physical Transmission Resources; 9.1 Overall Time-Frequency Structure; 9.2 Normal Subframes and MBSFN Subframes; 9.3 Carrier Aggregation; 9.4 Frequency-Domain Location of LTE Carriers; 9.5 Duplex Schemes; CHAPTER 10 Downlink Physical-Layer Processing; 10.1 Transport-Channel Processing; 10.2 Downlink Reference Signals; 10.3 Multi-Antenna Transmission; 10.4 Downlink L1/L2 Control Signaling CHAPTER 11 Uplink Physical-Layer Processing11.1 Transport-Channel Processing; 11.2 Uplink Reference Signals; 11.3 Uplink Multi-Antenna Transmission; 11.4 Uplink L1/L2 Control Signaling; 11.5 Uplink Timing Alignment; CHAPTER 12 Retransmission Protocols; 12.1 Hybrid ARQ with Soft Combining; 12.2 Radio-Link Control; CHAPTER 13 Power Control, Scheduling, and Interference Handling; 13.1 Uplink Power Control; 13.2 Scheduling and Rate Adaptation; 13.3 Inter-Cell Interference Coordination; 13.4 Heterogeneous Network Deployments; CHAPTER 14 Access Procedures; 14.1 Acquisition and Cell Search 14.2 System Information |
| Record Nr. | UNINA-9910785584803321 |
|
Dahlman Erik
|
||
| Oxford [U.K.] ; ; Burlington, Mass., : Academic Press, an imprint of Elsevier, 2011 | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
| ||
4G LTE/LTE-advanced for mobile broadband / / Erik Dahlman, Stefan Parkvall, and Johan Sköld
| 4G LTE/LTE-advanced for mobile broadband / / Erik Dahlman, Stefan Parkvall, and Johan Sköld |
| Autore | Dahlman Erik |
| Edizione | [1st edition] |
| Pubbl/distr/stampa | Oxford [U.K.] ; ; Burlington, Mass., : Academic Press, an imprint of Elsevier, 2011 |
| Descrizione fisica | 1 online resource (456 p.) |
| Disciplina |
384.5
621.38456 |
| Altri autori (Persone) |
ParkvallStefan
SköldJohan |
| Soggetto topico |
Long-Term Evolution (Telecommunications)
Broadband communication systems Mobile communication systems |
| ISBN |
1-283-17124-4
9786613171245 0-12-385490-3 |
| Formato | Materiale a stampa |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Nota di contenuto |
Front Cover; 4G LTE/LTE-Advanced for Mobile Broadband; Copyright Page; Contents; Preface; Acknowledgements; Abbreviations and Acronyms; CHAPTER 1 Background of LTE; 1.1 Introduction; 1.2 Evolution of Mobile Systems Before LTE; 1.3 ITU Activities; 1.4 Drivers for LTE; 1.5 Standardization of LTE; CHAPTER 2 High Data Rates in Mobile Communication; 2.1 High Data Rates: Fundamental Constraints; 2.2 Higher Data Rates Within a Limited Bandwidth: Higher-Order Modulation; 2.3 Wider Bandwidth Including Multi-Carrier Transmission; CHAPTER 3 OFDM Transmission; 3.1 Basic Principles of OFDM
3.2 OFDM Demodulation3.3 OFDM Implementation Using IFFT/FFT Processing; 3.4 Cyclic-Prefix Insertion; 3.5 Frequency-Domain Model of OFDM Transmission; 3.6 Channel Estimation and Reference Symbols; 3.7 Frequency Diversity with OFDM: Importance of Channel Coding; 3.8 Selection of Basic OFDM Parameters; 3.9 Variations in Instantaneous Transmission Power; 3.10 OFDM as a User-Multiplexing and Multiple-Access Scheme; 3.11 Multi-Cell Broadcast/Multicast Transmission and OFDM; CHAPTER 4 Wider-Band ""Single-Carrier"" Transmission; 4.1 Equalization Against Radio-Channel Frequency Selectivity 4.2 Uplink FDMA with Flexible Bandwidth Assignment4.3 DFT-Spread OFDM; CHAPTER 5 Multi-Antenna Techniques; 5.1 Multi-Antenna Configurations; 5.2 Benefits of Multi-Antenna Techniques; 5.3 Multiple Receive Antennas; 5.4 Multiple Transmit Antennas; 5.5 Spatial Multiplexing; CHAPTER 6 Scheduling, Link Adaptation, and Hybrid ARQ; 6.1 Link Adaptation: Power and Rate Control; 6.2 Channel-Dependent Scheduling; 6.3 Advanced Retransmission Schemes; 6.4 Hybrid ARQ with Soft Combining; CHAPTER 7 LTE Radio Access: An Overview; 7.1 Basic Principles; 7.2 LTE Release 9; 7.3 LTE Release 10 and IMT-Advanced 7.4 Terminal CapabilitiesCHAPTER 8 Radio-Interface Architecture; 8.1 Overall System Architecture; 8.2 Radio Protocol Architecture; 8.3 Control-Plane Protocols; CHAPTER 9 Physical Transmission Resources; 9.1 Overall Time-Frequency Structure; 9.2 Normal Subframes and MBSFN Subframes; 9.3 Carrier Aggregation; 9.4 Frequency-Domain Location of LTE Carriers; 9.5 Duplex Schemes; CHAPTER 10 Downlink Physical-Layer Processing; 10.1 Transport-Channel Processing; 10.2 Downlink Reference Signals; 10.3 Multi-Antenna Transmission; 10.4 Downlink L1/L2 Control Signaling CHAPTER 11 Uplink Physical-Layer Processing11.1 Transport-Channel Processing; 11.2 Uplink Reference Signals; 11.3 Uplink Multi-Antenna Transmission; 11.4 Uplink L1/L2 Control Signaling; 11.5 Uplink Timing Alignment; CHAPTER 12 Retransmission Protocols; 12.1 Hybrid ARQ with Soft Combining; 12.2 Radio-Link Control; CHAPTER 13 Power Control, Scheduling, and Interference Handling; 13.1 Uplink Power Control; 13.2 Scheduling and Rate Adaptation; 13.3 Inter-Cell Interference Coordination; 13.4 Heterogeneous Network Deployments; CHAPTER 14 Access Procedures; 14.1 Acquisition and Cell Search 14.2 System Information |
| Altri titoli varianti |
FourG LTE/LTE-Advanced for mobile broadband
Long-Term Evolution/Long-Term Evolution-Advanced for mobile broadband LTE-Advanced |
| Record Nr. | UNINA-9910825947003321 |
|
Dahlman Erik
|
||
| Oxford [U.K.] ; ; Burlington, Mass., : Academic Press, an imprint of Elsevier, 2011 | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
| ||
5G second phase explained : the 3GPP release 16 enhancements / / Jyrki Teppo Juho Penttinen
| 5G second phase explained : the 3GPP release 16 enhancements / / Jyrki Teppo Juho Penttinen |
| Autore | Penttinen Jyrki <1967-> |
| Pubbl/distr/stampa | Hoboken, New Jersey : , : John Wiley & Sons, Inc., , [2021] |
| Descrizione fisica | 1 online resource (315 pages) |
| Disciplina | 621.3845/6 |
| Soggetto topico |
5G mobile communication systems
Long-Term Evolution (Telecommunications) |
| ISBN |
1-119-64553-0
1-119-64555-7 1-119-64556-5 |
| Formato | Materiale a stampa |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Record Nr. | UNINA-9910554816203321 |
|
Penttinen Jyrki <1967->
|
||
| Hoboken, New Jersey : , : John Wiley & Sons, Inc., , [2021] | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
| ||
5G second phase explained : the 3GPP release 16 enhancements / / Jyrki Teppo Juho Penttinen
| 5G second phase explained : the 3GPP release 16 enhancements / / Jyrki Teppo Juho Penttinen |
| Autore | Penttinen Jyrki T. J. |
| Pubbl/distr/stampa | Hoboken, New Jersey : , : John Wiley & Sons, Inc., , [2021] |
| Descrizione fisica | 1 online resource (315 pages) |
| Disciplina | 621.3845/6 |
| Soggetto topico |
5G mobile communication systems
Long-Term Evolution (Telecommunications) |
| ISBN |
1-119-64553-0
1-119-64555-7 1-119-64556-5 |
| Formato | Materiale a stampa |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Record Nr. | UNINA-9910830059303321 |
|
Penttinen Jyrki T. J.
|
||
| Hoboken, New Jersey : , : John Wiley & Sons, Inc., , [2021] | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
| ||
Advanced Distribution Management System (ADMS) evaluations with private LTE communication networks / / Barry Mather
| Advanced Distribution Management System (ADMS) evaluations with private LTE communication networks / / Barry Mather |
| Autore | Mather Barry |
| Pubbl/distr/stampa | Golden, CO : , : National Renewable Energy Laboratory, , 2019 |
| Descrizione fisica | 1 online resource (12 pages) |
| Collana | NREL/PR |
| Soggetto topico |
Electric power distribution - United States
Electric power distribution - Computer simulation Long-Term Evolution (Telecommunications) |
| Formato | Materiale a stampa |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Altri titoli varianti | Advanced Distribution Management System |
| Record Nr. | UNINA-9910713861503321 |
|
Mather Barry
|
||
| Golden, CO : , : National Renewable Energy Laboratory, , 2019 | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
| ||
Deploying IPv6 in 3GPP networks : evolving mobile broadband from 2G to LTE and beyond / / Jouni Korhonen, Teemu Savolainen, Jonne Soininen
| Deploying IPv6 in 3GPP networks : evolving mobile broadband from 2G to LTE and beyond / / Jouni Korhonen, Teemu Savolainen, Jonne Soininen |
| Autore | Kaorhonen Jouni |
| Pubbl/distr/stampa | Chichester, West Sussex : , : John Wiley & Sons, , 2013 |
| Descrizione fisica | 1 online resource (400 p.) |
| Disciplina | 621.3845/6 |
| Altri autori (Persone) |
KorhonenJouni
SoininenJonne |
| Collana | Nsn/nokia series |
| Soggetto topico |
Long-Term Evolution (Telecommunications)
Cell phone systems Mobile computing TCP/IP (Computer network protocol) |
| ISBN |
1-118-39833-5
1-118-39832-7 1-299-46522-6 1-118-39831-9 |
| Formato | Materiale a stampa |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Nota di contenuto |
-- Foreword xvii -- Preface xix -- Acknowledgments xxi -- Acronyms xxiii -- Glossary xxxiii -- 1 Introduction 1 -- 1.1 Introduction to Internet and the Internet Protocol 2 -- 1.2 Internet Principles 2 -- 1.3 The Internet Protocol 4 -- 1.3.1 Networks of Networks 6 -- 1.3.2 Routing and Forwarding 7 -- 1.4 Internet Protocol Addresses 9 -- 1.4.1 IPv4 Addresses 9 -- 1.4.2 IPv6 Addresses 11 -- 1.5 Transport Protocols 12 -- 1.5.1 User Datagram Protocol 13 -- 1.5.2 Transmission Control Protocol 13 -- 1.5.3 Port Numbers and Services 14 -- 1.6 Domain Name Service 14 -- 1.6.1 DNS Structure 14 -- 1.6.2 DNS Operation 15 -- 1.6.3 Top Level Domain 16 -- 1.6.4 Internationalized Domain Names 17 -- 1.7 IPv4 Address Exhaustion 17 -- 1.7.1 IP Address Allocation 18 -- 1.7.2 History of IPv4 Address Exhaustion 19 -- 1.8 IPv6 History Thus Far 21 -- 1.8.1 IPv6 Technology Maturity 21 -- 1.8.2 IPv6 Network Deployments 22 -- 1.9 Ongoing Cellular Deployments 23 -- 1.10 Chapter Summary 24 -- 1.11 Suggested Reading 24 -- References 24 -- 2 Basics of the 3GPP Technologies 27 -- 2.1 Standardization and Specifications 27 -- 2.1.1 3GPP Standardization Process 28 -- 2.1.2 IETF Standardization Process 31 -- 2.1.3 Other Important Organizations in the 3GPP-Ecosystem 33 -- 2.2 Introduction to 3GPP Network Architecture and Protocols 34 -- 2.2.1 GSM System 34 -- 2.2.2 General Packet Radio Service 36 -- 2.2.3 Evolved Packet System 41 -- 2.2.4 Control and User Planes, and Transport and User Layer Separation 44 -- 2.3 3GPP Protocols 45 -- 2.3.1 Control-Plane Protocols 46 -- 2.3.2 User-Plane Protocols 53 -- 2.3.3 GPRS Tunneling Protocol Versions 55 -- 2.3.4 PMIP Based EPS Architecture 56 -- 2.4 Mobility and Roaming 58 -- 2.4.1 Mobility Management 59 -- 2.4.2 Roaming 60 -- 2.4.3 Mobility Management Beyond 3GPP 60 -- 2.5 Central Concepts for IP Connectivity 61 -- 2.5.1 PDP Contexts and EPS Bearers 61 -- 2.5.2 Access Point Name 63 -- 2.5.3 Traffic Flow Template 64 -- 2.5.4 3GPP Link Model Principles 65 -- 2.5.5 Multiple Packet Data Network Connections 67.
2.6 User Equipment 68 -- 2.6.1 Traditional 3GPP UE Model 69 -- 2.6.2 Split-UE 69 -- 2.7 Subscription Management Databases and Other Backend Systems 70 -- 2.7.1 Home Location Register and Authentication Center 70 -- 2.7.2 Home Subscriber Server 71 -- 2.7.3 Equipment Identity Register 71 -- 2.7.4 Other Backend Systems 71 -- 2.8 End-to-end View from the User Equipment to the Internet 72 -- 2.8.1 GPRS 72 -- 2.8.2 EPS 73 -- 2.9 Chapter Summary 75 -- 2.10 Suggested Reading 75 -- References 76 -- 3 Introduction to IPv6 79 -- 3.1 IPv6 Addressing Architecture 80 -- 3.1.1 IPv6 Address Format 80 -- 3.1.2 IPv6 Address Types 81 -- 3.1.3 IPv6 Address Scopes 81 -- 3.1.4 IPv6 Addressing Zones 82 -- 3.1.5 IPv6 Addresses on Network Interfaces 82 -- 3.1.6 Interface Identifier and the Modified EUI-64 83 -- 3.1.7 IPv6 Address Space Allocations 84 -- 3.1.8 Special IPv6 Address Formats 84 -- 3.1.9 Textual Presentations of IPv6 Addresses 86 -- 3.2 IPv6 Packet Header Structure and Extensibility 87 -- 3.2.1 Traffic Class and Flow Label 88 -- 3.2.2 IPv6 Extension Headers 90 -- 3.2.3 MTU and Fragmentation 92 -- 3.2.4 Multicast 94 -- 3.3 Internet Control Message Protocol Version 6 97 -- 3.3.1 Error Messages 98 -- 3.3.2 Informational Messages 100 -- 3.4 Neighbor Discovery Protocol 101 -- 3.4.1 Router Discovery 101 -- 3.4.2 Parameter Discovery 102 -- 3.4.3 On-link Determination 104 -- 3.4.4 Link-layer Address Resolution 104 -- 3.4.5 Neighbor Unreachability Detection 105 -- 3.4.6 Next-hop Determination 106 -- 3.4.7 Duplicate Address Detection 106 -- 3.4.8 Redirect 107 -- 3.4.9 Secure Neighbor Discovery 107 -- 3.4.10 Neighbor Discovery Proxies 108 -- 3.5 Address Configuration and Selection Approaches 109 -- 3.5.1 Stateless Address Autoconfiguration 110 -- 3.5.2 Dynamic Host Configuration Protocol Version 6 112 -- 3.5.3 IKEv2 117 -- 3.5.4 Address Selection 118 -- 3.5.5 Privacy and Cryptographically Generated Addresses 120 -- 3.5.6 Router Selection 121 -- 3.6 IPv6 Link Types and Models 122 -- 3.6.1 IPv6 over Point-to-point Links 123. 3.6.2 IPv6 over Shared Media 124 -- 3.6.3 Link Numbering 125 -- 3.6.4 Bridging of Link Types 126 -- 3.7 Mobile IP 126 -- 3.7.1 Detecting Network Attachment 126 -- 3.7.2 Host-based Mobile IP 127 -- 3.7.3 Network-based Mobile IP 128 -- 3.8 IP Security 130 -- 3.8.1 Security Protocols 131 -- 3.8.2 Security Associations 131 -- 3.8.3 Key Management 132 -- 3.8.4 Cryptographic Algorithms 132 -- 3.8.5 MOBIKE 132 -- 3.9 Application Programming Interfaces 133 -- 3.9.1 Socket APIs 133 -- 3.9.2 Address Family Agnostic APIs 133 -- 3.9.3 IP Address Literals and Unique Resource Identifiers 134 -- 3.9.4 Happy Eyeballs 134 -- 3.10 Implications of IPv6 for Other Protocols 136 -- 3.10.1 Transport Layer Protocols 136 -- 3.10.2 Domain Name System 137 -- 3.10.3 Applications 141 -- 3.10.4 Internet Routing 141 -- 3.10.5 Management Information Base 143 -- 3.11 Validation and Certification 144 -- 3.11.1 Test Suites 144 -- 3.11.2 IPv6 Ready Logo 144 -- 3.12 Example IPv6 Packet Flows 145 -- 3.12.1 IPv6 on Ethernet 146 -- 3.12.2 IPv6 with DNS and TCP 153 -- 3.13 Chapter Summary 155 -- References 156 -- 4 IPv6 in 3GPP Networks 163 -- 4.1 PDN Connectivity Service 163 -- 4.1.1 Bearer Concept 164 -- 4.1.2 PDP and PDN Types 166 -- 4.1.3 Link Models in 3GPP 168 -- 4.2 End User IPv6 Service Impact on the 3GPP System 172 -- 4.2.1 User, Control and Transport Planes 172 -- 4.2.2 Affected Networking Elements 173 -- 4.2.3 Charging and Billing 180 -- 4.2.4 External PDN Access and the (S)Gi Interface 182 -- 4.2.5 Roaming Challenges 187 -- 4.3 End User IPv6 Service Impact on GTP and PMIPv6 Protocols 189 -- 4.3.1 GTP Control Plane Version 1 189 -- 4.3.2 GTP Control Plane Version 2 191 -- 4.3.3 GTP User Plane 194 -- 4.3.4 PMIPv6 194 -- 4.4 IP Address Assignment, Configuration, and Management 195 -- 4.4.1 Addressing Assumptions 195 -- 4.4.2 Stateless IPv6 Address Autoconfiguration 197 -- 4.4.3 Stateful IPv6 Address Configuration 200 -- 4.4.4 Deferred Address Allocation 200 -- 4.4.5 Static IPv6 Addressing 201 -- 4.4.6 IPv6 Prefix Delegation 204. 4.4.7 NAS Protocol Signaling and PCO Options 207 -- 4.4.8 Initial E-UTRAN Attach Example with IPv4 and IPv6 Address Configuration 211 -- 4.5 Bearer Establishment and Fallback Scenarios 214 -- 4.5.1 Initial Connection Establishment 214 -- 4.5.2 Backward Compatibility with Earlier Releases 215 -- 4.5.3 Dual Address Bearer Flag 215 -- 4.5.4 Requested PDN Type Handling in a PGW 216 -- 4.5.5 Fallback Scenarios and Rules 217 -- 4.5.6 Inter-RAT Handovers and Inter-SGSN Routing Area Updates 218 -- 4.6 Signaling Interfaces 219 -- 4.6.1 IPv6 as Transport 219 -- 4.6.2 IPv6 in Information Element Level 219 -- 4.7 User Equipment Specific Considerations 220 -- 4.7.1 IPv6 and Impacted Layers 220 -- 4.7.2 Required RFCs for Host UEs 222 -- 4.7.3 DNS Issues 223 -- 4.7.4 Provisioning 224 -- 4.7.5 IPv6 Tethering 225 -- 4.7.6 IPv6 Application Support 227 -- 4.8 Multicast 227 -- 4.9 Known IPv6 Issues and Anomalies 228 -- 4.9.1 IPv6 Neighbor Discovery Considerations 229 -- 4.9.2 PDN Connection Model and Multiple IPv6 Prefixes 233 -- 4.10 IPv6 Specific Security Considerations 233 -- 4.10.1 IPv6 Addressing Threats 234 -- 4.10.2 IPv6 First-hop Security 236 -- 4.10.3 IPv6 Extension Header Exploits 237 -- 4.11 Chapter Summary 239 -- References 240 -- 5 IPv6 Transition Mechanisms for 3GPP Networks 248 -- 5.1 Motivation for Transition Mechanisms 248 -- 5.1.1 Phasing the Transition 250 -- 5.2 Technology Overview 251 -- 5.2.1 Translation 251 -- 5.2.2 Encapsulation 253 -- 5.2.3 Mesh or Hub-and-spoke 254 -- 5.2.4 Scalability Concerns 255 -- 5.3 Transition Toolbox 255 -- 5.3.1 Transition Solutions Not Included 256 -- 5.3.2 Dual-stack 257 -- 5.3.3 NAT64 and DNS64 258 -- 5.3.4 464XLAT 269 -- 5.3.5 Bump-In-the-Host 271 -- 5.3.6 Mapping Address and Port Number 272 -- 5.3.7 Other Tunneling or Translation Based Transition Mechanisms 275 -- 5.4 Transition Scenarios for 3GPP 277 -- 5.4.1 Transition Scenario Evolution 278 -- 5.4.2 Dual-stack 280 -- 5.4.3 IPv6-only 281 -- 5.4.4 Double Translation 281 -- 5.5 Transition Impacts on 3GPP Architecture 282. 5.5.1 Transition Impact on the Supporting Infrastructure 282 -- 5.5.2 IP Network Support Systems 283 -- 5.5.3 Tools to Divide Subscribers Per IP Capability 285 -- 5.5.4 Translation Implications 286 -- 5.5.5 Transition Support in the Transport Plane 287 -- 5.5.6 Roaming 287 -- 5.5.7 Impact of Delayed Transition to IPv6 288 -- 5.6 Transitioning to IPv6 289 -- 5.6.1 Application Developer's Transition Plan 290 -- 5.6.2 Phone Vendor's Transition Plan 290 -- 5.6.3 Network Operator's Transition Checklist 290 -- 5.7 Chapter Summary 292 -- References 293 -- 6 Future of IPv6 in 3GPP Networks 296 -- 6.1 IPv6-based Traffic Offloading Solutions 296 -- 6.1.1 Motivations in Cellular Networks 297 -- 6.1.2 Benefits of IPv6-based Offloading Approaches 299 -- 6.1.3 IP-friendly Offloading Solutions 299 -- 6.1.4 Concluding Remarks 303 -- 6.2 Evolving 3GPP Bearers to Multiple Prefixes and Next-hop Routers 304 -- 6.2.1 Background and Motivation 304 -- 6.2.2 Multi-prefix Bearer Solution Proposal 305 -- 6.2.3 Overall Impact Analysis 311 -- 6.2.4 Open Issues and Future Work 313 -- 6.3 LTE as the Uplink Access for Home Networks 313 -- 6.3.1 Homenet at IETF 313 -- 6.3.2 Homenet and 3GPP Architecture 314 -- 6.3.3 Additional 3GPP Deployment Options 315 -- 6.4 Port Control Protocol 316 -- 6.4.1 Deployment Scenarios 317 -- 6.4.2 Protocol Features 318 -- 6.4.3 PCP Server Discovery 319 -- 6.4.4 Protocol Messages 319 -- 6.4.5 Cascaded NATs 320 -- 6.4.6 Relation to IPv6 Transition 320 -- 6.5 Internet of Things 321 -- 6.5.1 Typical Use Cases 321 -- 6.5.2 Standardization Organizations Working with IoT 322 -- 6.5.3 IoT Domain from the 3GPP Point of View 327 -- 6.5.4 Implications to UEs 328 -- 6.5.5 Implications to 3GPP Networks 329 -- 6.6 Chapter Summary 331 -- References 332 -- Index 337. |
| Record Nr. | UNINA-9910139010203321 |
|
Kaorhonen Jouni
|
||
| Chichester, West Sussex : , : John Wiley & Sons, , 2013 | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
| ||
Deploying IPv6 in 3GPP networks : evolving mobile broadband from 2G to LTE and beyond / / Jouni Korhonen, Teemu Savolainen, Jonne Soininen
| Deploying IPv6 in 3GPP networks : evolving mobile broadband from 2G to LTE and beyond / / Jouni Korhonen, Teemu Savolainen, Jonne Soininen |
| Autore | Kaorhonen Jouni |
| Pubbl/distr/stampa | Chichester, West Sussex : , : John Wiley & Sons, , 2013 |
| Descrizione fisica | 1 online resource (400 p.) |
| Disciplina | 621.3845/6 |
| Altri autori (Persone) |
KorhonenJouni
SoininenJonne |
| Collana | Nsn/nokia series |
| Soggetto topico |
Long-Term Evolution (Telecommunications)
Cell phone systems Mobile computing TCP/IP (Computer network protocol) |
| ISBN |
1-118-39833-5
1-118-39832-7 1-299-46522-6 1-118-39831-9 |
| Formato | Materiale a stampa |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Nota di contenuto |
-- Foreword xvii -- Preface xix -- Acknowledgments xxi -- Acronyms xxiii -- Glossary xxxiii -- 1 Introduction 1 -- 1.1 Introduction to Internet and the Internet Protocol 2 -- 1.2 Internet Principles 2 -- 1.3 The Internet Protocol 4 -- 1.3.1 Networks of Networks 6 -- 1.3.2 Routing and Forwarding 7 -- 1.4 Internet Protocol Addresses 9 -- 1.4.1 IPv4 Addresses 9 -- 1.4.2 IPv6 Addresses 11 -- 1.5 Transport Protocols 12 -- 1.5.1 User Datagram Protocol 13 -- 1.5.2 Transmission Control Protocol 13 -- 1.5.3 Port Numbers and Services 14 -- 1.6 Domain Name Service 14 -- 1.6.1 DNS Structure 14 -- 1.6.2 DNS Operation 15 -- 1.6.3 Top Level Domain 16 -- 1.6.4 Internationalized Domain Names 17 -- 1.7 IPv4 Address Exhaustion 17 -- 1.7.1 IP Address Allocation 18 -- 1.7.2 History of IPv4 Address Exhaustion 19 -- 1.8 IPv6 History Thus Far 21 -- 1.8.1 IPv6 Technology Maturity 21 -- 1.8.2 IPv6 Network Deployments 22 -- 1.9 Ongoing Cellular Deployments 23 -- 1.10 Chapter Summary 24 -- 1.11 Suggested Reading 24 -- References 24 -- 2 Basics of the 3GPP Technologies 27 -- 2.1 Standardization and Specifications 27 -- 2.1.1 3GPP Standardization Process 28 -- 2.1.2 IETF Standardization Process 31 -- 2.1.3 Other Important Organizations in the 3GPP-Ecosystem 33 -- 2.2 Introduction to 3GPP Network Architecture and Protocols 34 -- 2.2.1 GSM System 34 -- 2.2.2 General Packet Radio Service 36 -- 2.2.3 Evolved Packet System 41 -- 2.2.4 Control and User Planes, and Transport and User Layer Separation 44 -- 2.3 3GPP Protocols 45 -- 2.3.1 Control-Plane Protocols 46 -- 2.3.2 User-Plane Protocols 53 -- 2.3.3 GPRS Tunneling Protocol Versions 55 -- 2.3.4 PMIP Based EPS Architecture 56 -- 2.4 Mobility and Roaming 58 -- 2.4.1 Mobility Management 59 -- 2.4.2 Roaming 60 -- 2.4.3 Mobility Management Beyond 3GPP 60 -- 2.5 Central Concepts for IP Connectivity 61 -- 2.5.1 PDP Contexts and EPS Bearers 61 -- 2.5.2 Access Point Name 63 -- 2.5.3 Traffic Flow Template 64 -- 2.5.4 3GPP Link Model Principles 65 -- 2.5.5 Multiple Packet Data Network Connections 67.
2.6 User Equipment 68 -- 2.6.1 Traditional 3GPP UE Model 69 -- 2.6.2 Split-UE 69 -- 2.7 Subscription Management Databases and Other Backend Systems 70 -- 2.7.1 Home Location Register and Authentication Center 70 -- 2.7.2 Home Subscriber Server 71 -- 2.7.3 Equipment Identity Register 71 -- 2.7.4 Other Backend Systems 71 -- 2.8 End-to-end View from the User Equipment to the Internet 72 -- 2.8.1 GPRS 72 -- 2.8.2 EPS 73 -- 2.9 Chapter Summary 75 -- 2.10 Suggested Reading 75 -- References 76 -- 3 Introduction to IPv6 79 -- 3.1 IPv6 Addressing Architecture 80 -- 3.1.1 IPv6 Address Format 80 -- 3.1.2 IPv6 Address Types 81 -- 3.1.3 IPv6 Address Scopes 81 -- 3.1.4 IPv6 Addressing Zones 82 -- 3.1.5 IPv6 Addresses on Network Interfaces 82 -- 3.1.6 Interface Identifier and the Modified EUI-64 83 -- 3.1.7 IPv6 Address Space Allocations 84 -- 3.1.8 Special IPv6 Address Formats 84 -- 3.1.9 Textual Presentations of IPv6 Addresses 86 -- 3.2 IPv6 Packet Header Structure and Extensibility 87 -- 3.2.1 Traffic Class and Flow Label 88 -- 3.2.2 IPv6 Extension Headers 90 -- 3.2.3 MTU and Fragmentation 92 -- 3.2.4 Multicast 94 -- 3.3 Internet Control Message Protocol Version 6 97 -- 3.3.1 Error Messages 98 -- 3.3.2 Informational Messages 100 -- 3.4 Neighbor Discovery Protocol 101 -- 3.4.1 Router Discovery 101 -- 3.4.2 Parameter Discovery 102 -- 3.4.3 On-link Determination 104 -- 3.4.4 Link-layer Address Resolution 104 -- 3.4.5 Neighbor Unreachability Detection 105 -- 3.4.6 Next-hop Determination 106 -- 3.4.7 Duplicate Address Detection 106 -- 3.4.8 Redirect 107 -- 3.4.9 Secure Neighbor Discovery 107 -- 3.4.10 Neighbor Discovery Proxies 108 -- 3.5 Address Configuration and Selection Approaches 109 -- 3.5.1 Stateless Address Autoconfiguration 110 -- 3.5.2 Dynamic Host Configuration Protocol Version 6 112 -- 3.5.3 IKEv2 117 -- 3.5.4 Address Selection 118 -- 3.5.5 Privacy and Cryptographically Generated Addresses 120 -- 3.5.6 Router Selection 121 -- 3.6 IPv6 Link Types and Models 122 -- 3.6.1 IPv6 over Point-to-point Links 123. 3.6.2 IPv6 over Shared Media 124 -- 3.6.3 Link Numbering 125 -- 3.6.4 Bridging of Link Types 126 -- 3.7 Mobile IP 126 -- 3.7.1 Detecting Network Attachment 126 -- 3.7.2 Host-based Mobile IP 127 -- 3.7.3 Network-based Mobile IP 128 -- 3.8 IP Security 130 -- 3.8.1 Security Protocols 131 -- 3.8.2 Security Associations 131 -- 3.8.3 Key Management 132 -- 3.8.4 Cryptographic Algorithms 132 -- 3.8.5 MOBIKE 132 -- 3.9 Application Programming Interfaces 133 -- 3.9.1 Socket APIs 133 -- 3.9.2 Address Family Agnostic APIs 133 -- 3.9.3 IP Address Literals and Unique Resource Identifiers 134 -- 3.9.4 Happy Eyeballs 134 -- 3.10 Implications of IPv6 for Other Protocols 136 -- 3.10.1 Transport Layer Protocols 136 -- 3.10.2 Domain Name System 137 -- 3.10.3 Applications 141 -- 3.10.4 Internet Routing 141 -- 3.10.5 Management Information Base 143 -- 3.11 Validation and Certification 144 -- 3.11.1 Test Suites 144 -- 3.11.2 IPv6 Ready Logo 144 -- 3.12 Example IPv6 Packet Flows 145 -- 3.12.1 IPv6 on Ethernet 146 -- 3.12.2 IPv6 with DNS and TCP 153 -- 3.13 Chapter Summary 155 -- References 156 -- 4 IPv6 in 3GPP Networks 163 -- 4.1 PDN Connectivity Service 163 -- 4.1.1 Bearer Concept 164 -- 4.1.2 PDP and PDN Types 166 -- 4.1.3 Link Models in 3GPP 168 -- 4.2 End User IPv6 Service Impact on the 3GPP System 172 -- 4.2.1 User, Control and Transport Planes 172 -- 4.2.2 Affected Networking Elements 173 -- 4.2.3 Charging and Billing 180 -- 4.2.4 External PDN Access and the (S)Gi Interface 182 -- 4.2.5 Roaming Challenges 187 -- 4.3 End User IPv6 Service Impact on GTP and PMIPv6 Protocols 189 -- 4.3.1 GTP Control Plane Version 1 189 -- 4.3.2 GTP Control Plane Version 2 191 -- 4.3.3 GTP User Plane 194 -- 4.3.4 PMIPv6 194 -- 4.4 IP Address Assignment, Configuration, and Management 195 -- 4.4.1 Addressing Assumptions 195 -- 4.4.2 Stateless IPv6 Address Autoconfiguration 197 -- 4.4.3 Stateful IPv6 Address Configuration 200 -- 4.4.4 Deferred Address Allocation 200 -- 4.4.5 Static IPv6 Addressing 201 -- 4.4.6 IPv6 Prefix Delegation 204. 4.4.7 NAS Protocol Signaling and PCO Options 207 -- 4.4.8 Initial E-UTRAN Attach Example with IPv4 and IPv6 Address Configuration 211 -- 4.5 Bearer Establishment and Fallback Scenarios 214 -- 4.5.1 Initial Connection Establishment 214 -- 4.5.2 Backward Compatibility with Earlier Releases 215 -- 4.5.3 Dual Address Bearer Flag 215 -- 4.5.4 Requested PDN Type Handling in a PGW 216 -- 4.5.5 Fallback Scenarios and Rules 217 -- 4.5.6 Inter-RAT Handovers and Inter-SGSN Routing Area Updates 218 -- 4.6 Signaling Interfaces 219 -- 4.6.1 IPv6 as Transport 219 -- 4.6.2 IPv6 in Information Element Level 219 -- 4.7 User Equipment Specific Considerations 220 -- 4.7.1 IPv6 and Impacted Layers 220 -- 4.7.2 Required RFCs for Host UEs 222 -- 4.7.3 DNS Issues 223 -- 4.7.4 Provisioning 224 -- 4.7.5 IPv6 Tethering 225 -- 4.7.6 IPv6 Application Support 227 -- 4.8 Multicast 227 -- 4.9 Known IPv6 Issues and Anomalies 228 -- 4.9.1 IPv6 Neighbor Discovery Considerations 229 -- 4.9.2 PDN Connection Model and Multiple IPv6 Prefixes 233 -- 4.10 IPv6 Specific Security Considerations 233 -- 4.10.1 IPv6 Addressing Threats 234 -- 4.10.2 IPv6 First-hop Security 236 -- 4.10.3 IPv6 Extension Header Exploits 237 -- 4.11 Chapter Summary 239 -- References 240 -- 5 IPv6 Transition Mechanisms for 3GPP Networks 248 -- 5.1 Motivation for Transition Mechanisms 248 -- 5.1.1 Phasing the Transition 250 -- 5.2 Technology Overview 251 -- 5.2.1 Translation 251 -- 5.2.2 Encapsulation 253 -- 5.2.3 Mesh or Hub-and-spoke 254 -- 5.2.4 Scalability Concerns 255 -- 5.3 Transition Toolbox 255 -- 5.3.1 Transition Solutions Not Included 256 -- 5.3.2 Dual-stack 257 -- 5.3.3 NAT64 and DNS64 258 -- 5.3.4 464XLAT 269 -- 5.3.5 Bump-In-the-Host 271 -- 5.3.6 Mapping Address and Port Number 272 -- 5.3.7 Other Tunneling or Translation Based Transition Mechanisms 275 -- 5.4 Transition Scenarios for 3GPP 277 -- 5.4.1 Transition Scenario Evolution 278 -- 5.4.2 Dual-stack 280 -- 5.4.3 IPv6-only 281 -- 5.4.4 Double Translation 281 -- 5.5 Transition Impacts on 3GPP Architecture 282. 5.5.1 Transition Impact on the Supporting Infrastructure 282 -- 5.5.2 IP Network Support Systems 283 -- 5.5.3 Tools to Divide Subscribers Per IP Capability 285 -- 5.5.4 Translation Implications 286 -- 5.5.5 Transition Support in the Transport Plane 287 -- 5.5.6 Roaming 287 -- 5.5.7 Impact of Delayed Transition to IPv6 288 -- 5.6 Transitioning to IPv6 289 -- 5.6.1 Application Developer's Transition Plan 290 -- 5.6.2 Phone Vendor's Transition Plan 290 -- 5.6.3 Network Operator's Transition Checklist 290 -- 5.7 Chapter Summary 292 -- References 293 -- 6 Future of IPv6 in 3GPP Networks 296 -- 6.1 IPv6-based Traffic Offloading Solutions 296 -- 6.1.1 Motivations in Cellular Networks 297 -- 6.1.2 Benefits of IPv6-based Offloading Approaches 299 -- 6.1.3 IP-friendly Offloading Solutions 299 -- 6.1.4 Concluding Remarks 303 -- 6.2 Evolving 3GPP Bearers to Multiple Prefixes and Next-hop Routers 304 -- 6.2.1 Background and Motivation 304 -- 6.2.2 Multi-prefix Bearer Solution Proposal 305 -- 6.2.3 Overall Impact Analysis 311 -- 6.2.4 Open Issues and Future Work 313 -- 6.3 LTE as the Uplink Access for Home Networks 313 -- 6.3.1 Homenet at IETF 313 -- 6.3.2 Homenet and 3GPP Architecture 314 -- 6.3.3 Additional 3GPP Deployment Options 315 -- 6.4 Port Control Protocol 316 -- 6.4.1 Deployment Scenarios 317 -- 6.4.2 Protocol Features 318 -- 6.4.3 PCP Server Discovery 319 -- 6.4.4 Protocol Messages 319 -- 6.4.5 Cascaded NATs 320 -- 6.4.6 Relation to IPv6 Transition 320 -- 6.5 Internet of Things 321 -- 6.5.1 Typical Use Cases 321 -- 6.5.2 Standardization Organizations Working with IoT 322 -- 6.5.3 IoT Domain from the 3GPP Point of View 327 -- 6.5.4 Implications to UEs 328 -- 6.5.5 Implications to 3GPP Networks 329 -- 6.6 Chapter Summary 331 -- References 332 -- Index 337. |
| Record Nr. | UNINA-9910808658703321 |
|
Kaorhonen Jouni
|
||
| Chichester, West Sussex : , : John Wiley & Sons, , 2013 | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
| ||
