Home Page Icon
Home Page
Table of Contents for
List of Figures
Close
List of Figures
by Jean-Gabriel Remy, Charlotte Letamendia
LTE Standards
Cover
Contents
Title Page
Copyright
List of Figures
List of Tables
Introduction
I.1. Mobile communication systems: 0G, 1G, 2G, 3G, 4G and 5G
I.2. High speed broadband mobile services: what the customers are waiting for
1 LTE Standards and Architecture
1.1. 3rd generation partnership project (3GPP)
1.2. LTE – numbering and addressing
1.3. LTE architecture overview
1.4. Radio access subsystem: eUTRAN (also called eUTRA)
1.5. Core network
1.6. LTE – roaming architecture
1.7. SIM for communications privacy
1.8. Glossary
1.9. Appendix 1: Complete submission of 3GPP LTE release 10 and beyond (LTE-advanced) under step 3 of the IMT-advanced process
1.10. Appendix 2: GPRS Tunneling Protocol (GTP)
1.11. Appendix 3: The SGW implementation by CISCO
1.12. Appendix 4: AT&T has LTE small cells “in the lab": Source Dan Janes, Site Editor, Light Reading mobile [JON 13]
2 OFDMA
2.1. What is OFDM/OFDMA?
2.2. General principles
2.3. LTE channel: bandwidths and characteristics
2.4. OFDM applied to LTE
2.5. OFDMA in the LTE radio subsystem: OFDMA and SCFDMA in LTE
2.6. Appendix 1: the constraints of mobile radio
2.7. Appendix 2: Example of OFDM/OFDMA technological implementation Innovative DSP
2.8. Appendix 3: LTE error correction on the radio path [WIK 14d]
2.9. Appendix 4: The 700 MHz frequencies in the USA for LTE
3 The Full IP Core Network
3.1. Fixed mobile convergence
3.2. IP multimedia subsystem
3.3. Evolved packet system in 3 GPP standards
3.4. Telephony processing
3.5. The requirements of VoLTE and V.VoIP applications
3.6. Voice and video over LTE are achieved using voice on IP channels (VoLTE)
3.7. Cut down version of IMS
3.8. Latency management
3.9. Appendix 1 : VoIP tests in UK
4 LTE Security. SIM/USIM Subsystem
4.1. LTE security
4.2. SIM card
Appendix
Bibliography
Index
Search in book...
Toggle Font Controls
Playlists
Add To
Create new playlist
Name your new playlist
Playlist description (optional)
Cancel
Create playlist
Sign In
Email address
Password
Forgot Password?
Create account
Login
or
Continue with Facebook
Continue with Google
Sign Up
Full Name
Email address
Confirm Email Address
Password
Login
Create account
or
Continue with Facebook
Continue with Google
Prev
Previous Chapter
Copyright
Next
Next Chapter
List of Tables
List of Figures
Introduction
I.1. LTE and LTE Advanced logo
I.2. The LTE project: milestones. Short history of the birth of a worldwide standard
I.3. 3GGP logo
Chapter 1
1.1. Organizational Partners’ deliverables
1.2. LTE architecture
1.3. UTRAN and E-UTRAN
1.4. LTE general architecture
1.5. Protocol stacks operating at S1 and S5/S8 interfaces
1.6. UE-MSC
1.7. EPC/SAE
1.8. The complete set of network elements and standardized signaling interfaces of LTE
1.9. LTE subsystems and connections
1.10. LTE interfaces
1.11. 3GPP image for eUTRAN
1.12. Tools from Rohde & Schwartz
1.13. Description of eUTRAN with its interfaces
1.14. E-UTRAN architecture with HeNodeB GW and HeNodeB
1.15. X2 interface
1.16. This shows the enhancements in release 10 and release 11
1.17. Functional split between E-UTRAN and EPC [3GPP TS 36.300]
1.18. Radio frequency protocol
1.19. User plane
1.20. Protocol stack for the control plane between the UE and MME
1.21. Structure
1.22. Token
1.23. Physical layer
1.24. Signaling channel mapping
1.25. Functions of the different layers
1.26. The protocol chain from IP packets to transport blocks
1.27. Optimization of the repartition of carriers
1.28. Single-user MIMO
1.29. MIMO signal processing
1.30. Spatial multiplexing MIMO sector rate
1.31. Heterogeneous network (4G Americas)
1.32. Core network
1.33. Three subsystems
1.34. LTE network elements
1.35. LTE interfaces
1.36. Protocol stack of S1-MME interface
1.37. Protocol stack of S3 interface
1.38. Protocol stack of S4 interface
1.39. Protocol stack of interface S5 or S8
1.40. Protocol stack of S10 interface
1.41. Protocol stack of S11 interface
1.42. Protocol stack of S6a interface
1.43. Protocol stack of S13 interface
1.44. Protocol stack of SBc interface
1.45. User plane
1.46. Protocol stack of S1-U interface
1.47. Protocol stacks of S4 interfaces used to connect UE from 2G network to PDN
1.48. Protocol stacks of S4 interfaces used to connect UE from 3G network to PDN
1.49. Protocol stack of S12 interface used to connect UE from 3G network to PDN
1.50. E-UTRAN and the EPC
1.51. UE is moving from old to new RAN coverage provided by eNodeB
1.52. S1-based handover
1.53. S1-based handover reject scenario
1.54. Rooming architecture
1.55. Non-roaming architecture by 3GPP
1.56. Roaming architecture scenario with home routed traffic
1.57. Roaming architecture for local breakout, with home operator’s application functions only
1.58. Roaming architecture for local breakout, with home visitor’s application functions only
1.59. Security architecture
1.60. The process for authentication and ciphering
1.61. Kc Key
1.62. RAND and Ki
1.63. Ki
1.64. TMSI, Kc, RAND and SRES
1.65. Schema of the structure of a SIM card
1.66. SIM
1.67. GTP present at the interface between eNodeB and S-GW
1.68. GTP between S-GW and P-GW
1.69. GPRS tunneling protocol in LTE
1.70. GPRS tunneling protocol Types
Chapter 2
2.1. OFDM frequency and time domain
2.2. OFDMA subcarriers
2.3. OFDM frequency
2.4. Channels
2.5. OFDM techniques
2.6. Cyclic prefix
2.7. Transformation
2.8. Effect of multipath propagation
2.9. LTE OFDMA in the downlink
2.10. 16 QAM modulation: 4 bits per symbol
2.11. LTE RB allocation
2.12. Uplink
2.13. SC-FDMA spreads the data symbols all over the system bandwidth
2.14. Localized mapping and distributed mapping
2.15. SC-FDMA and OFDMA. DFT: discrete Fourier transform
2.16. LTE OFDMA physical layer structure LTE physical layer uses multiple OFDMA subcarriers and symbols separated by guard intervals
2.17. LTE resource blocks and resource elements (from the 3GPP standard)
2.18. CDF PAPR comparison for OFDMA used in the LTE downlink, and SC-FDMA localized mode (LFDMA) used in the LTE uplink – 256 total subcarriers, 64 subcarrier per user, 0.5 roll-off factor, a) QPSK, b) 16 QAM
2.19. Some LTE resource elements are reserved for control channel and reference signals only a subset are used for user data, thus lowering actual throughput
2.20. Conventional OFDMA with cyclic prefix
2.21. Downlink: OFDMA transmission scheme: downlink physical layer processing chain
2.22. Transmitter scheme of SC-FDMA
2.23. OFDMA and SC-FDMA
2.24. Number of DL/UL component carriers
Chapter 3
3.1. IMS
3.2. IMS wide scope
3.3. IMS functions
3.4. Security aspects of early IMS and non-3GPP systems
3.5. Full scope of EPS
3.6. PCRF connections in LTE’s EPC
3.7. Evolved packet core
3.8. EPC components
3.9. Cut down version of IMS Reduced IMS network for VoLTE
3.10. Latency (50 ms)
Chapter 4
4.1. LTE needs a layered security
4.2. Layered security model
4.3. LTE eUTRAN protocole stack
4.4. Derivation of successive keys
4.5. LTE keys hierarchy as in 3GPP TS 36.300
4.6. EPS security
4.7. IPsec
4.8. (U)SIM cards as released by the operator
4.9. Structure of the UICC electronic chip
4.10. UICC form factors
4.11. UICC contacts
4.12. NFC applications of the UICC
4.13. Example of UICC architecture
4.14. The complex structure of UICC applications in a modern device
4.15. The complex links of (U)SIM with the LTE world as seen by Telenor
4.16. UICC structure with ISIM
4.17. Example of ISIM application: digital right management, as seen by Telenor
4.18. Example of OTA use for non-telecommunication applications
Add Highlight
No Comment
..................Content has been hidden....................
You can't read the all page of ebook, please click
here
login for view all page.
Day Mode
Cloud Mode
Night Mode
Reset