LTE @ Yogyakarta, 19 December 2001
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LTE @ Opening The Gates To 4G Mobile Yogyakarta, 19 December 2009
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LTE @ Yogyakarta, 19 December 2001
- 1. Arief Hamdani Gunawan Yogyakarta, 19 December 2009
- 7. 3G deployment in the world China Mobile NTT DoCoMo ( 2010 ) KDDI Verizon ( 2009 ) AT&T W ( 2010 ) Vodafone ( 2011 ) T-Mobile ( 2010 ) China Telecom HSPA+ DL>40MBps; UL>10Mbps TD-HSDPA 2.8~8.4Mbps TD-HSUPA 2.2~6.6Mbps WCDMA 384Kbps HSDPA 1.8/3.6Mbps HSDPA 7.2Mbps HSUPA 1.4~5.8Mbps LTE TDD DL:100Mbps UL:50Mbps TD-HSPA+ DL:>25.2Mbps UL:>19.2Mbps EV-DO Rel. 0 DL: 2.4Mbps UL:153.6kbps cdma2000 1x 153.6kbps D0 Rel. A DL: 3.1Mbps UL: 1.8Mbps Do Rev B (Multi Carrier DO) DL : 46.5Mbps UL: 27Mbps LTE FDD DL:100Mbps UL:50Mbps LTE TDD1 LTE TDD2
- 8. Trend of B3G ITU IMT-Advanced(4G) UMB + 100Mbps-1Gbps 100Mbps~ 1Gbps LTE+ FDD/TDD DL:100Mbps UL:50Mbps LTE-FDD WIMAX 3GPP 3GPP2 B3G EV-DO Rel. 0 DL: 2.4Mbps UL:153.6kbps cdma2000 1x 153.6kbps D0 Rel. A DL: 3.1Mbps UL: 1.8Mbps Do Rev B ( 多载波 DO ) DL : 46.5Mbps UL: 27Mbps UMB DL: 100Mbps UL: 50Mbps TD-HSPA+ DL:>25.2Mbps UL:>19.2Mbps TD-HSDPA 2.8~8.4Mbps TD-HSUPA 2.2~6.6Mbps HSPA+ DL>40MBps; UL>10Mbps WCDMA 384Kbps HSDPA 1.8/3.6Mbps HSDPA 7.2Mbps HSUPA 1.4~5.8Mbps GREAN ~600kbps GPRS/EDGE ~ 200kbps LTE-TDD DL:100Mbps UL:50Mbps 16m 100Mbps~1Gbps Mobile WiMAX Wave1 15Mbps Mobile WiMAX Wave2 30Mbps
- 9. 4G Technologies Mobile WiMAX 3GPP IP E2E Network IP E2E Network CKT Switched Network OFDMA - Based CDMA - Based IMT- Advanced 2008 2009 2010 2011 2012
- 10. Evolution of UMTS FDD and TDD driven by data rate and latency requirements
- 11. Technologies for the LTE Multicarrier Technology Multiple Antenna Technology Packet-Switched Radio Interface User Equipment Capabilities Three fundamental benefits of multiple antennas: (a) diversity gain; (b) array gain; (c) spatial multiplexing gain.
- 13. LTE will Ensure the Success of Mobile Internet
- 14. LTE Offers 10-30x Improvement on cost/performance vs. existing technologies
- 15. LTE The Right Solution for Mobile Internet
- 16. What’s Happening in Mobile Internet World -- Device Providers --
- 20. Simplified LTE network elements and interfaces 3GPP TS 36.300 Figure 4: Overall Architecture eNB = E-UTRAN Node B All radio interface-related functions MME = Mobile Management entity – Manages mobility, UE identity, and security parameters. S-GW = Serving Gateway – Node that terminates the interface towards E-UTRAN. P-GW = PDN (Packet Data Network) Gateway – Node that terminates the interface towards PDN.
- 22. PDCP = Packet Data Convergence Protocol RRC = Radio Resource Control RLC = Radio Link Control
- 23. Protocol
- 34. SAE architecture [3GPP TS 23.401] Evolved Packet Core S11 S2 S3 S4 S7 S6 SGi S1 Gb Iu Rx+ X1 X1 X2 Evolved RAN aGW S5 GERAN UTRAN GPRS Core MME UPE SAE GW PCRF Operator IP services (including IMS, PSS, ...) Non-3GPP IP Access eNB eNB PDN SAE GW HSS
- 35. SAE architechture [3GPP TS 23.401] S1 TBD S8 X2 Operator IP service, including IMS S11 S11 S5 SGi Evolved RAN IASA aGW = MME/UPE S6a S7 TBD eNB TBD eNB aGW eNB SAE GW PDN SAE GW HSS PCRF aGW
- 39. Functions S1
- 42. GTP-U tunneling SAE GW UPE eNB Server UE L1 L2 X1 S1 S11 SGi S5 PDN SAE GW Header compression & encryption Radio L1 MAC PDCP IPv6/v4 u Application TCP/UDP RLC L1 L2 IP UDP GTP-U L2 L1 IP UDP GTP-U L2 L1 IP UDP GTP-U L2 L1 IPv6/v4 TCP/UDP Application L1 L2 IP UDP GTP-U L2 L1 IP UDP GTP-U L2 L1 IP UDP GTP-U L2 L1 Radio L1 MAC RLC PDCP ENC
- 43. Non-3GPP access tunneling PDN SAE GW HA AP Server UE IP L2 L1 IPv6/v4 TCP/UDP Application L1 L2 WLAN S2 SGi L2 L1 IP MIP IPv4/6 IP UDP IP MIP IPv4/6 UDP IP L2 L1 IP L2 L1 L1 L2 L1 L2
- 45. Channel Mapping
- 52. FDD (left) and TDD (right) frequency bands defined in the 3GPP (May 2009)
- 63. The LTE downlink physical resource based on OFDM
- 64. Parameters for downlink generic frame structure
- 67. Downlink reference signal structure
- 69. P-SCH and S-SCH structure
- 72. DL Physical Channel Processing
- 73. LTE frame structure type 1 (FDD), downlink
- 74. LTE frame structure type 2 (TDD)
- 81. SC-FDMA in comparison with OFDMA and DS-CDMA/FDE
- 82. SC-FDMA signal generation Localized vs. distributed FDMA
- 84. Parameters for uplink generic structure
- 88. UL Physical Channel Processing
- 90. Spatial Multiplexing Spatial multiplexing allows to transmit different streams of data simultaneously on the same downlink resource block(s). These data streams can belong to one single user (single user MIMO / SU-MIMO) or to different users (multi user MIMO / MU-MIMO). While SU-MIMO increases the data rate of one user, MU-MIMO allows to increase the overall capacity. Spatial multiplexing is only possible if the mobile radio channel allows it.
- 91. LTE MIMO concept
- 94. Collaborative/Network MIMO overview Coordinate transmission and reception of signals among multiple bases. Reduces intercell interference and improves cell-edge performance and overall throughput. Collaborative MIMO : share user data and long-term noncoherent channel information. Coherent network MIMO : share user data and short-term coherent channel information.
- 103. [email_address] Thank You !
Notas del editor
- Short descriptions of the LTE interfaces [Source: ]