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Cellular Networks and Mobile Computing COMS 6998-8, Spring 2012

Cellular Networks and Mobile Computing COMS 6998-8, Spring 2012. Instructor: Li Erran Li ( lierranli@cs.columbia.edu ) http:// www.cs.columbia.edu /~coms6998-8 / 1 /30/ 2012: Cellular Networks : LTE. Outline. Air interface Architecture. Cellular Comms Evolution. LTE.

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Cellular Networks and Mobile Computing COMS 6998-8, Spring 2012

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  1. Cellular Networks and Mobile ComputingCOMS 6998-8, Spring 2012 Instructor: Li Erran Li (lierranli@cs.columbia.edu) http://www.cs.columbia.edu/~coms6998-8/ 1/30/2012: Cellular Networks: LTE

  2. Outline • Air interface • Architecture Cellular Networks and Mobile Computing (COMS 6998-8)

  3. Cellular Comms Evolution LTE • 3GPP – collaboration for 3G based on GSM • 3GPP2 – collaboration for 3G based on IS-95

  4. LTE PHY Basics • Six bandwidths • 1.4, 3, 5, 10, 15, and 20 MHz • Two modes • FDD and TDD • 100 Mbps DL (SISO) and 50 Mbps UL • Transmission technology • OFDM for multipath resistance • DL OFDMA for multiple access in frequency/time • UL SC-FDMA to deal with PAPR ratio problem

  5. Frame Structure Frame Structure Type 1 (FDD) Frame Structure Type 2 (TDD)

  6. : : Resource grid One downlink slot, Tslot • 6 or 7 OFDM symbols in 1 slot • Subcarrier spacing = 15 kHz • Block of 12 SCs in 1 slot = 1 RB • 0.5 ms x 180 kHz • Smallest unit of allocation 6 or 7 OFDM symbols Resource block Transmission BW Resource element 12subcarriers l=0 l=6

  7. 2-D time and frequency grid #19 #18 #17 #16 1 radio frame = 10 msec (307200 x Ts) Time #5 #4 #3 #2 Sub-frame #1 NscRB subcarriers (=12) #0 Power 1 slot = 0.5 msec Frequency NBWDL subcarriers

  8. DL PHY Channels and Signals • Signals: generated in PHY layers • P-SS: used for initial sync • S-SS: frame boundary determination • RS: pilots for channel estimation and tracking • Channels: carry data from higher layers • PBCH: broadcast cell-specific info • PDCCH: channel allocation and control info • PCFICH: info on size of PDCCH • PHICH: Ack/Nack for UL blocks • PDSCH: Dynamically allocated user data

  9. QPSK 16QAM 64QAM P-SCH - Primary Synchronization Signal S-SCH - Secondary Synchronization Signal PBCH - Physical Broadcast Channel PDCCH -Physical Downlink Control Channel PDSCH - Physical Downlink Shared Channel Reference Signal – (Pilot) Time Frequency DL Channel Mapping

  10. UL PHY Signals and Channels • Signals: generated in the PHY layer • Demodulation RS : sync and channel estimation • SRS: Channel quality estimation • Channels: carry data from higher layers • PUSCH: Uplink data • PUCCH: UL control info • PRACH: Random access for connection establishment

  11. PUSCHDemodulation Reference Signal(for PUSCH) PUCCH Demodulation Reference Signal(for PUCCH format 0 or 1, Normal CP) UL Channel Mapping 64QAM16QAMQPSK QPSK BPSK Time Frequency

  12. MIMO in LTE • Rel 8 defines MIMO only for DL • 1, 2 and 4 transmit antennas defined for • Transmit Diversity (TxDiv) • Spatial Multiplexing (SpMux) • Control channels undergo TxDiv based on SFBC • Data channels may undergo TxDiv or SpMux

  13. Orthogonal RS locations • channel matrix needs to be known in advance for equalization

  14. Thank you!

  15. Backup slides

  16. SC-FDMA

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