1Marius Pesavento, Willem Mulder, Femto Forum Plenary, June 2010, Reading, UK mimoOn

LTE Tutorial part 1LTE Basics

Marius Pesavento - marius.pesavento@mimoOn.deWillem Mulder - willem.mulder@mimoOn.de

2Marius Pesavento, Willem Mulder, Femto Forum Plenary, June 2010, Reading, UK mimoOn

Agenda

Part 1, LTE Basics 9:30 10:30 Introduction to LTE FDD/TDD frame structures and reference signals Physical channels, logical channels PHY signal processing architecture H-ARQ processing, H-ARQ timing UE categories

Part 2, Advanced topics in LTE 11:00 12:30 The LTE MIMO modes Codebook-based precoding Closed loop operation CQI reporting modes Using antenna port 5 (SDMA) techniques Simulation results Outlook LTE Advanced

Q & A 12:30 13:00

3Marius Pesavento, Willem Mulder, Femto Forum Plenary, June 2010, Reading, UK mimoOn

3G Evolution

HSPA evolution Gradually improved performance at low additional cost in 5MHz spectrum

allocation Next step: dual carrier allocation (10MHz)

LTE LTE is new Radio Access Network (RAN) significantly improved performance in up to 20MHz allocation Peak data rates up to 300Mbps

LTE-Advanced natural evolution of LTE, next major step toward IMT-Advanced support spectrum aggregation up to 100MHz and data rate up to 1Gbps

SPRING 2011

4Marius Pesavento, Willem Mulder, Femto Forum Plenary, June 2010, Reading, UK mimoOn

LTE Targets

Cell-capacity (Control plane): 200 user per cell in 5MHz Peak data rate

DL: 300MBit/s UL: 75 MBit/s

Control plane latency: 50/100ms (idle to active) User Plane Latency:

5Marius Pesavento, Willem Mulder, Femto Forum Plenary, June 2010, Reading, UK mimoOn

E-UTRA frequency bands

TDDN/A2400 MHz-2300 MHz2400 MHz-2300 MHz40

TDDN/A1920 MHz-1880 MHz1920 MHz-1880 MHz39

TDDN/A2620 MHz2570 MHz2620 MHz2570 MHz 38

TDDN/A1930 MHz1910 MHz1930 MHz1910 MHz 37

TDDN/A1990 MHz1930 MHz1990 MHz1930 MHz 36

TDDN/A1910 MHz1850 MHz1910 MHz1850 MHz 35

TDDN/A2025 MHz2010 MHz 2025 MHz 2010 MHz34

TDDN/A1920 MHz1900 MHz1920 MHz1900 MHz33

...

FDD20768 MHz758 MHz798 MHz788 MHz14

FDD21756 MHz746 MHz787 MHz777 MHz13

FDD[TBD][TBD][TBD][TBD][TBD]12

FDD23 MHz1500.9 MHz1475.9MHz1452.9 MHz1427.9MHz

11

FDD340 MHz 2170 MHz2110 MHz1770 MHz1710 MHz10

FDD60 MHz1879.9 MHz1844.9MHz1784.9 MHz1749.9MHz9

FDD10 MHz960 MHz925 MHz915 MHz880 MHz8

FDD50 MHz2690 MHz2620 MHz2570 MHz2500 MHz7

FDD35 MHz885 MHz875 MHz840 MHz830 MHz6

FDD20 MHz894MHz869 MHz849 MHz824 MHz5

FDD355 MHz2155 MHz2110 MHz1755 MHz 1710 MHz4

FDD20 MHz1880 MHz1805 MHz1785 MHz1710 MHz 3

FDD20 MHz1990 MHz1930 MHz1910 MHz1850 MHz 2

FDD130 MHz2170 MHz2110 MHz 1980 MHz1920 MHz 1

FDL_low-FUL_highFDL_low FDL_highFUL_low FUL_high

Duplex Mode

UL-DL Band separation

Downlink (DL)eNode B transmit

UE receive

Uplink (UL)eNode B receive

UE transmit

E-UTRA Band

UMTS band

extension band

6Marius Pesavento, Willem Mulder, Femto Forum Plenary, June 2010, Reading, UK mimoOn

Basic Transmission Schemes

Transmission Bandwidth 1.4 MHz 3 MHz 5 MHz 10 MHz 15 MHz 20 MHz

Sampling Frequency 1.92 MHz 3.84 MHz 7.68 MHz

15.36 MHz

23.04 MHz 30.72 MHz

FFT Size 128 256 512 1024 1536 2048

#RBs (12 subcarrier)

6 15 25 50 75100

(110)

7Marius Pesavento, Willem Mulder, Femto Forum Plenary, June 2010, Reading, UK mimoOn

Frame Structure Type 1

Frame Structure Type 1

frame structure type 1 is applicable to FDD (frequency division duplex), full-duplex and half-duplex

#0 #1 #2 #3 #18 #19

one slot, Tslot = 15360*TS = 0.5 ms

one radio frame, Tf = 307200*TS = 10 ms

one subframeTransmission Time Interval

(TTI)= 1ms

TS basic time unit corresponding to sampling frequency 30.72MHz

8Marius Pesavento, Willem Mulder, Femto Forum Plenary, June 2010, Reading, UK mimoOn

Slot Structure

normal cyclic prefix

extended cyclic prefix, f = 15 KHz

normal cyclic prefix #2normal cyclic prefix #1

2048*TS144*TS 2048*TS2048*TS2048*TS2048*TS2048*TS2048*TS

160*TS 144*TS144*TS144*TS144*TS144*TS

slot

#0 #6

extended cyclic prefix

#0 #5

2048*TS512*TS2048*TS

512*TS2048*TS512*TS2048*TS

512*TS2048*TS512*TS2048*TS

512*TS

slot

9Marius Pesavento, Willem Mulder, Femto Forum Plenary, June 2010, Reading, UK mimoOn

subframe 1 ms

one radio frame, Tf = 307200*TS = 10 ms

Frame Structure Type 2: TDD

DL#0

S#1

UL#2

UL/DL#3

UL/DL#4

S/DL#6

DL#5

UL/DL#7

UL/DL#8

UL/DL#9

Downlinksubframe

Uplinksubframe

Special guardsubframe for

DL to UL switch

Special guardsubframe orDownlink SF

Uplink orDownlinksubframe

special subframe: DL to UL switching

S#1 or #6

DwPTSGP UpPTS

DwPTS: DL pilot time slotshortend DL subframe

(3,8,9,10,11, or 12 OFDM symbols) reference signals, primary sync and control, PDSCH

GP: Guard period(1,2,3,4,7,8,9,10 OFDM symbols)

UpPTS: UL pilot time slot(1 or 2 OFDM symbols)

sounding reference or RACH

SS

SR

S a

ndC

ontro

lP

SS

0 1 2

10Marius Pesavento, Willem Mulder, Femto Forum Plenary, June 2010, Reading, UK mimoOn

Frame Structure Type 2: TDD

Tx

Rx

Tx

Rx

DL UL Tx#2UL Tx

#3GP

UpP

TS

Dw

PTS

DL UL Rx#2UL Rx

#3GP

UpP

TS

Dw

PTS

DL Tx#0

DL Tx#4

DL Tx#6

DL Tx#5G

P

UpP

TS

Dw

PTS

DL DL Rx#4DL Rx

#6DL Rx

#5GP

UpP

TS

Dw

PTS

pathdelay

pathdelay

UL/DL switching must be accomplished within the CP length

(e.g. if path delay is zero)

11Marius Pesavento, Willem Mulder, Femto Forum Plenary, June 2010, Reading, UK mimoOn

DwPTS, GP, UpPTS length(in OFDM symbols)

FormatNormal CP Extended CP

DwPTS GP UpPTS DwPTS GP UpPTS

0 3 10

1

38

666.7s 200Km

11 9 4 8 3

2 10 3 9 2

3 11 2 10 1

4 12 1 3 7

25 3 9

2

8 2

6 9 3 9 1

7 10 2 - - -

8 11 1 - - -

12Marius Pesavento, Willem Mulder, Femto Forum Plenary, June 2010, Reading, UK mimoOn

Resource Blocks

7 OFDM symbols

12 subcarriers

frame structure 1

normal cyclic prefix

f = 15 KHz

DC

1DLRB Nresource block

resource block 0

all subframes

13Marius Pesavento, Willem Mulder, Femto Forum Plenary, June 2010, Reading, UK mimoOn

Physical ChannelsDownlink (DL)

Physical Broadcast Channel (PBCH) System Information (Master Information Block

MIB) approx. every 40 ms Physical Downlink Control Channel (PDCCH)

DL Control Information Format (DCI-format), DL-grants (current TTI), UL-grants (+4 TTI), uplink power control

Physical DL Shared Channel (PDSCH) DL transport blocks (TBs), DL Control Information,

System Information Block (SIB), Paging Channel (PCH), Multicast Channel (MCH)

Physical Control Format Indicator Channel (PCFICH) location of the PDCCH

Physical Hybrid ARQ Indicator Channel (PHICH) UL ACK/NACK

Physical Multicast Channel (PMCH)

14Marius Pesavento, Willem Mulder, Femto Forum Plenary, June 2010, Reading, UK mimoOn

Physical ChannelsUplink (UL)

Physical Random Access Channel (PRACH) UL timing estimation (path delay), UL

scheduling request (SR) Physical Uplink Control Channel (PUCCH)

Channel Quality Indicater (CQI), Precoding Matrix Indicator (PMI), Rank Indicator (RI), ACK/NACK, SR

Physical Uplink Shared Channel (PUSCH) UL TBs, ACK/NACK, CQI, PMI, RI, SR

15Marius Pesavento, Willem Mulder, Femto Forum Plenary, June 2010, Reading, UK mimoOn

PHY Signals

Downlink Primary and Secondary Synchronization Signal

cell-search, DL-frame synchronization, time, frequency, drift, Cell-specific reference signals (antenna port 0 - 3),

orthogonal (non-overlapping) in time-frequency-domain MIMO channel estimation, fine frequency estimation, UL-CQI

estimation

UE-specific reference signals implicit signaling of DL-transmit beamforming weights

Uplink Demodulaton Reference Signal Sounding Reference Signal

UL wideband CQI estimation Random-Access Sequence

for UL timing synchronization

16Marius Pesavento, Willem Mulder, Femto Forum Plenary, June 2010, Reading, UK mimoOn

one antenna port(frame structure 1,

normal cyclic prefix)

reference signal 0

two antenna ports(frame structure 1,

normal cyclic prefix)

reference signal 0

reference signal 1

not used for transmissionon this antenna port

slot slot slot

Cell-Specific Reference Signals

carrier frequency: 2.6GHzLTE requirement

max speed: 350km/hmax Doppler frequency: 843Hz

Clarke's modelcoherence time: T > 9/(16 fm)

approx. 3 OFDM symbols

pilot spacing in frequencycoherence bandwidth B 6x15KHz

B 1 / (2 ) delay spead :

1 / (2 B) =1.77sec ( 54 smpls; corresp. to 531 meter )

Port 0 Port 1

Port 0Tx

Tx

17Marius Pesavento, Willem Mulder, Femto Forum Plenary, June 2010, Reading, UK mimoOn

reference signal 0

reference signal 1

not used for transmissionon this antenna port

reference signal 2

reference signal 3

four antenna ports(frame structure 1,

normal cyclic prefix)

slot slot even slot odd slot even slot odd slot

Cell-Specific Reference Signals

Port 3

Port 2

Port 1

Port 0Tx

18Marius Pesavento, Willem Mulder, Femto Forum Plenary, June 2010, Reading, UK mimoOn

DL time-frequency structure

DL payload on DL Shared ChannelPrimary synchronization signal Secondary synchronization signalBroadcast ChannelDL Control ChannelReference signal

20MHz 30.72MHz

guard band

19Marius Pesavento, Willem Mulder, Femto Forum Plenary, June 2010, Reading, UK mimoOn

UL time-frequency structure

demodulation reference

signal (DRS)

soundingreference

signal (SRS)

PUSCH

PUCCH

time / OFDM symbol number

frequ

ency

20Marius Pesavento, Willem Mulder, Femto Forum Plenary, June 2010, Reading, UK mimoOn

MAC PDU

CB

Seg

-m

enta

tion

Mod

ulat

ion

Layer Mapping

MIMO Precoding

P/S Sync Signals

RefSignal

Frame Builder

IFFT CP AddingPulse Shape

Cha

nnel

Cod

ing

Turb

o

HARQ Support& Rate Matching

HARQ hard buffer for S1, P1, P2

Subblock interleaverRate Matcher, RVs S

cram

blin

g

to DACs

TB C

RC

CB

CR

C

CB

C

onca

tena

tion

PDSCH Tx

num

bero

fan

tenn

as

number ofTransport Blocks (TBs)

number ofstreams

21Marius Pesavento, Willem Mulder, Femto Forum Plenary, June 2010, Reading, UK mimoOn

MAC PDU

frame/RBdemapper

RotatorFreq. Off.

CP Removal FFT

Channel Estimation

Measure-ments

MIMO Detector

FromADCs

Layer Demapper

P/S-Sync Processing

CB

Con

cate

-na

tion

Soft

Dem

odul

ator

8

bit

Turb

oD

ecod

er

HARQ Support & Rate Matching:

HARQ soft buffer for S1, P1, P2,

Subblock interleaverSoft-Combiner 8 bit, RVs D

escr

ambl

ing

TB C

RC

CB

CR

C

CB

sem

enta

tion:

tran

sitio

n fr

om

OFD

M w

ise

to

CB

-wis

e pr

oces

sing

antenna ports

Down-sampling

filter

Fine Frequency estimation

RotatorSamp.D. other CWs

smple drift

PDSCH Rx

22Marius Pesavento, Willem Mulder, Femto Forum Plenary, June 2010, Reading, UK mimoOn

Transform Precoding

Mixed-Radix DFT

Demod. Ref.

Signal

RBResource Mapper

IFFT CPAddingPulse Shape DAC

RotatorFreq. Cor.

MAC PDU

CB

Seg

-m

enta

tion

Mod

ulat

ion

Cha

nnel

Turb

o C

odin

g

Dat

a &

Con

trol

M

ux

Scra

mbl

ing

TB C

RC

CB

CR

C

CB

C

onca

tena

tionHARQ Support

& Rate MatchingHARQ hard buffer for S1,

P1, P2 Subblock interleaver

Rate Matcher, RVs

RotatorSamp.

Drift

Sound. Ref.

Signal

controlTS36.212Figure

5.2.2-1

Cha

nnel

Inte

rleav

ing

ACK RI

Length 32 block code

CQI and/or PMI reportCQI 11 bit

32bit

Cha

nnel

Con

v.

Cod

ing

CB

CR

CRate Matching

PUSCH Tx

number of Transport Blocks (TBs) of different users

to reduce PAPR

23Marius Pesavento, Willem Mulder, Femto Forum Plenary, June 2010, Reading, UK mimoOn

controlTS36.212Figure

5.2.2-1

MAC PDU

CB

Con

cate

-na

tion

Soft

dem

odul

ator

8.bi

t

Turb

oD

ecod

er

Des

cram

blin

g

TB C

RC

CB

CR

C

CB

Seg

men

tatio

n:Tr

ansi

tion

from

O

FDM

-to

CB

-wis

e pr

oces

sing

Tranform (De)Precoding(mixed-Radix

DFT)

frame/RB Demapper

CP Removal FFT

Demod. Ref.Channel Estimation

Measure-ments

Multi-AntennaReceiver

Sounding Ref.Processing

Dat

a &

Con

trol

D

emux

Frame timing

HARQ Support & Rate Matching:

HARQ soft buffer for S1, P1, P2,

Subblock interleaverSoft-Combiner 8 bit, RVs

FromADCs

Cha

nnel

de

inte

rleav

er

ACK RIBlock decoder(32,11)

Rate DeMatching:Subblock interleaver

Soft-Combiner 8 bit, RVsViterbiCB CRC

PUSCH Rx

24Marius Pesavento, Willem Mulder, Femto Forum Plenary, June 2010, Reading, UK mimoOn

Downlink Control Indicator Format (DCI format)

DCI format 0 is used for the transmission of UL-SCH assignments DCI format 1 is used for the transmission of DL-SCH assignments

for single antenna operation DCI format 1A is used for a compact transmission of DL-SCH

assignments for single antenna operation DCI format 1B is used to support closed-loop single-rank

transmission with possibly contiguous resource allocation DCI format 1C is for downlink transmission of paging, RACH

response and dynamic BCCH scheduling DCI format 2 is used for the transmission of DL-SCH assignments

for MIMO operation DCI format 3 is used for the transmission of TPC commands for

PUCCH and PUSCH with 2-bit power adjustments DCI format 3A is used for the transmission of TPC commands for

PUCCH and PUSCH with single bit power adjustments

25Marius Pesavento, Willem Mulder, Femto Forum Plenary, June 2010, Reading, UK mimoOn

CRC scramblingwith RNTI /(UE Tx port)

specific

CRCgeneration

L=16

DCI tail bit convolutional

encoder, rate 1/3

interleaver,rate-matching

PDCCHmultiplexing element

insertion

cell-specificscrambling

other DCIs

QPSKmodulation

sub-block interleaver(on quadruples of modulated symbols), remove

elements

Resource Mapper,(mapping to RE groups)

time first then frequency

layer mapping,pre-coding:

single antenna port or transmit

diversity

antenna ports 0,...,3

other DL channels

IFFT andCP attachment

MIMOchannel

FFT andCP removal,

frequency and timing correction

Resource demapper(1-3 OFDM symbols,

according to CFI)

sub-block de-inter-leaver

equalizer, MIMO detector,

(requires channel estimation)

soft-demodulator

rate-dematching,

deinterleaving

Viterbi decoder

cell specific de-

scrambling

44 blind decoding attempts (common-

and UE-specific-search-space),

44 PDCCHcandidates

code bit extractionCRC calculation

XOR

CRC extraction

RNTIskip some decodes if RNTI is found

PDCCH processing chain

RNTI: radio network temporary identifier

DCI

User specific search space

(aggregation level)1-CCE (2x6attempts)2-CCE (2x6attempts)4-CCE (2x2attempts),8-CCE (2x2attempts)

Cell specific search space

(aggregation level)4-CCE (2x4attempts)8-CCE (2x2attempts)

26Marius Pesavento, Willem Mulder, Femto Forum Plenary, June 2010, Reading, UK mimoOn

spreading with

sequence

Schedulingrequest (SR)(presence/absence)

Block codeLength 20

never simultaneously with PUSCH

CQI, PMI,RI report (2)

27Marius Pesavento, Willem Mulder, Femto Forum Plenary, June 2010, Reading, UK mimoOn

Resource de-mapper(k,l,slot#)

form

at 2

,2a,

2b

(CQ

I,PM

I,RI)

CP removal

FFT (2048)

format 1,1a,1bACK/NCK w or w/o SR(see next page)

multiplication with

conjugate of

)()(, nr vu

12PUCCHseq =N

resource index (2)PUCCHn

determines cyclic shift

IDFT

leng

th 1

2 separateusers

accordingto cyclic shift in time-

domain

multiplication with

conjugate of

)()(, nr vu

12PUCCHseq =N

resource index (2)PUCCHn

determines cyclic shift

IDFT

leng

th 1

2 channel estimation

separate users accordingto cyclic shift in time-

domain

tap M(

28Marius Pesavento, Willem Mulder, Femto Forum Plenary, June 2010, Reading, UK mimoOn

Resource de-mapper(k,l,slot#)

on SRresource

form

at 1

,1a,

1b

(SR a

nd A

CK/N

ACK)

CP removal

FFT (2048)

format 2,2a,2b(CQI,PMI,RI)

multiplication with

conjugate of

)()(, nr vu

12PUCCHseq =N

resource index (2)PUCCHn

determines cyclic shift

IDFT

leng

th 1

2 separateusers

accordingto cyclic shift in time-

domain

multiplication with

conjugate of

)()(, nr vu

12PUCCHseq =N

resource index (2)PUCCHn

determines cyclic shift

IDFT

leng

th 1

2channel

estimation 1

separate users according to cyclic shift in time-domain

tap M(

29Marius Pesavento, Willem Mulder, Femto Forum Plenary, June 2010, Reading, UK mimoOn

Resource de-mapper(k,l,slot#)

on ACK/NACK

resource

form

at 1

,1a,

1b

(SR a

nd A

CK/N

ACK)

CP removal

FFT (2048)

format 2,2a,2b(CQI,PMI,RI)

multiplication with

conjugate of

)()(, nr vu

12PUCCHseq =N

resource index (2)PUCCHndetermines cyclic shift

IDFT

leng

th 1

2 separateusers

accordingto cyclic shift in time-

domain

multiplication with

conjugate of

)()(, nr vu

12PUCCHseq =N

resource index (2)PUCCHn

determines cyclic shift

IDFT

leng

th 1

2channel

estimation 1

separate users according to cyclic shift in time-domain

tap M(

30Marius Pesavento, Willem Mulder, Femto Forum Plenary, June 2010, Reading, UK mimoOn

spreading with

sequence

formapping to outerRBs

formapping to inRBs

Pseudo-Randomsequence generator

cellIDinit Nc =

(2)RBN

(1)csN

),(cellcs lnn s

)()(, nr vu

12PUCCHseq =N

spreading with

orthogonalsequence

12 s

ymbol

s

)(oc

iwn

4PUCCHSF =N

UE specificcell specific

scrambling

spreading with

sequence

)()(, nr vu

12PUCCHseq =N

modulation:d(0),d(19)

on QPSK36.211, 7.1d(20), d(21)according to

36.211, Table 5.4.2-1

resource index (2)PUCCHn

determines cyclic shift

Resourcemapper

(k,l,slot#)

IFFT

CP attach

(1)PUCCHnresource index

determines cyclic shiftand orthogonal sequence

12 s

ymbol

s

input sequence for format 1

input sequence for format 2

Demodulation reference signals for PUCCH format 2

31Marius Pesavento, Willem Mulder, Femto Forum Plenary, June 2010, Reading, UK mimoOn

3 xrepetition

ACK/NACK1 bit

BPSK(I or Q)

symbol levelSpreading,

length 4 orthogonal sequence

3bit

super-positionof different

ACK/NACKS

3 symbols 12 symbols

resource mapper,PHICH group is

mapped to 3 groups of 4 REs

scrambling

12 s

ymbol

s

layer mapperSISO or MIMO TD

FFT / CP insertion

MIMOchannel

CP removal/IFFT

resource demapperMIMO detectordescrambling

matched filterlength(12)

ACK/NACK1 bit

other ACK/NACK1 bit

other ACK/NACK1 bit

Location depends on the index of the first RB of the corresponding PUSCH transmission

PHICH(DL HARQ)

Max. 8 different sequences

Selection depends on the index of the first RB of the corresponding PUSCH transmission

32Marius Pesavento, Willem Mulder, Femto Forum Plenary, June 2010, Reading, UK mimoOn

MIB

cell specificscrambling scrambling

tail bit convolutional

encoder, rate 1/3

QPSK modulation

layer mapping forsingle antenna or transmit diversity

precodingSFD

resourcemapping

IFFTCP inclusion

MIMOchannel

CP removelFFT

Equalization(SISO, MISO, or TD)

soft demodulator

(QPSK)

channel estimates

Viterbi decoder

interleaver,rate-matching

rate matching buffer

CRC attachCRC mask

code bit extraction, CRC

computationantenna config

CRC extaction

XOR

antenna config

frame no 0,1,2,3

PBCH

PBCH carries important PHY information:system bandwidth, number of transmit antennas, PHICH configuration and system frame number,

maskedCRC

mask

MIB

After successful reception of PBCH, UE can read D-BCH in

PDSCH (including PCFICH and PDCCH) which carries system

information not including in PBCH

33Marius Pesavento, Willem Mulder, Femto Forum Plenary, June 2010, Reading, UK mimoOn

possible cell specificroot-sequences,(conjugate)

RACH sequence extends over several slots

CP inclusion(3168, 21024,

6240)

add to OFDM frame in time

domain

UL Tx signal in time domain:PUSCH, PUCCH,DRS,SRS,including CP

Channelphase rotation,

(mixing,frequency shift to DC)

decimation1/24

LP filter1/24DFT 1024Multiplication

IDFT 1024(results in change of

sampling rate)

Peak dection,path delay estimation

RACH sequence, associated timing-advance

RACH sequence, associated timing-advance

Zadoff-Chu sequence (L=839), selectec from set of 64 sequences),different root-sequences or different cyclic shifts, Create in 839 sequence in frequency domain

Zero padding to 1024

IDFT of length 1024

Upsampling by 24,

LP filtering

Rotator, frequency

shift

PRACH

correlation (convolution) in time domainreplaced by multiplication in frequency domain

34Marius Pesavento, Willem Mulder, Femto Forum Plenary, June 2010, Reading, UK mimoOn

PCFICHDL Control Format

block codeL=16

2 bits scamblingcell and

subframe dependent

modulatorQPSK

layer mapping

FFT / CP insertion

power boosting

power control

MIMOchannel

resourcemapper

(4 blocks of 4REs = 1RE

group)

cell ID

precodingSISO or

Tx diversity

CP removalII

FFT

resource demap

MIMO detectiondemodulatordescrambling

blockdetection

number ofOFDM symbolsreserve for control1,2,3

35Marius Pesavento, Willem Mulder, Femto Forum Plenary, June 2010, Reading, UK mimoOn

Rate matching and HARQ processing

systematicparity 1parity 2

sub-blockinterleaver

column permutation

write-in row-wise

read-out column-wise S1

P1P2

MUX

S1

P1/P2

RV0

RV2

RV3

RV1

36Marius Pesavento, Willem Mulder, Femto Forum Plenary, June 2010, Reading, UK mimoOn

HARQ timing

37Marius Pesavento, Willem Mulder, Femto Forum Plenary, June 2010, Reading, UK mimoOn

UE Categories synchronous HARQ in UL, ACK/NACK in 4 TTI after UL reception,

re-transmission (UL) in 8 TTI after initial transmission, total of 8 HARQ processes asynchronous HARQ in DL, ACK/NACK in 4 TTI after DL reception, retransmission

with DL scheduling grant, total number of 8 HARQ processes

Downlink physical layer parameter values set by UE Category

UE CategoryMaximum number of DL-SCH transport block bits received

within a TTI

Maximum number of bits of a DL-SCH transport

block received within a TTI

Total number of soft

channel bits

Maximum number of supported layers for

spatial multiplexing in DL

Category 1 10296 10296 250368 1

Category 2 51024 51024 1237248 2

Category 3 102048 75376 1237248 2

Category 4 150752 75376 1827072 2

Category 5 302752 151376 3667200 4

Uplink physical layer parameter values set by UE Category

UE Category

Maximum number of bits of an UL-SCH transport block transmitted within a TTI

Support for 64QAM in UL

Category 1 5160 No

Category 2 25456 No

Category 3 51024 No

Category 4 51024 No

Category 5 75376 Yes

8HARQ bufferx(3(S1,P1,P2)x10296+

12(termination))

38Marius Pesavento, Willem Mulder, Femto Forum Plenary, June 2010, Reading, UK mimoOn

UE Categories

39Marius Pesavento, Willem Mulder, Femto Forum Plenary, June 2010, Reading, UK mimoOn

TDD: DL grants and ACK/NACK reporting

FDD: only one DL (and one UL) grant per TTI. Corresponding DL TBs need to be ACK/NACK 4 TTIs after reception (1 or 2 bits).

TDD: ACK/NACK required for detected PDSCH and for DL SPS release on PDCCH.

TDD: usually one DL grant (but up to 2 DL grants, in special case of UL-DL config. 0) can be received within one TTI.

40Marius Pesavento, Willem Mulder, Femto Forum Plenary, June 2010, Reading, UK mimoOn

subframe 1 ms

one radio frame, Tf = 307200*TS = 10 ms

TDD ACK/NACKRecall: Frame Structure Type 2: TDD

DL#0

S#1

UL#2

UL/DL#3

UL/DL#4

S/DL#6

DL#5

UL/DL#7

UL/DL#8

UL/DL#9

Downlinksubframe

Uplinksubframe

Special guardsubframe for

DL to UL switch

Special guardsubframe orDownlink SF

Uplink orDownlinksubframe

special subframe: DL to UL switching

S#1 or #6

DwPTSGP UpPTS

DwPTS: DL pilot time slotshortend DL subframe

(3,8,9,10,11, or 12 OFDM symbols) reference signals, primary sync and control, PDSCH

GP: Guard period(1,2,3,4,7,8,9,10 OFDM symbols)

UpPTS: UL pilot time slot(1 or 2 OFDM symbols)

sounding reference or RACH

SS

SR

S a

ndC

ontro

lP

SS

0 1 2

41Marius Pesavento, Willem Mulder, Femto Forum Plenary, June 2010, Reading, UK mimoOn

TDD: UE ACK/NACK procedure(PUSCH transmission and PHICH reception)

TDD UL/DLConfiguration

subframe number i

0 1 2 3 4 5 6 7 8 9

0 6,7 4 6,7 4

1 4 6 4 6

2 6 6

3 6 6 6

4 6 6

5 6

6 6 4 7 4 6

ACK/NACK received on PHICHin subframe ifor UL transmission in subframe i - k,where the values for k are given inthe table.

k for TDD configurartion 0-6

TDD UL/DLConfiguration

subframe number i

0 1 2 3 4 5 6 7 8 9

0 4 7 6 4 7 6

1 4 6 4 6

2 6 6

3 6 6 6

4 6 6

5 6

6 4 6 6 4 7

UE Rx Perspectivefor UL transmission in subframe i,ACK/NACK received on PHICH in subframe i + k, where the values for k are given inthe table.

k for TDD configurartion 0-6

UE Tx Perspective

42Marius Pesavento, Willem Mulder, Femto Forum Plenary, June 2010, Reading, UK mimoOn

DL control issues in TDD DL HARQ

TDD UL/DLConfig.

DL subframe number n

0 1 2 3 4 5 6 7 8 9

0 4 6 4 6

1 7 6 4 7 6 4

2 7 6 4 8 7 6 4 8

3 4 11 7 6 6 5 5

4 12 11 8 7 7 6 5 4

5 12 11 9 8 7 6 5 4 13

6 7 7 7 7 5

reception of PDSCH in subframe nACK/NACK on PUSCH or PUCCH in subframe n + k

k for TDD configurartion 0-6

TDD UL/DLConfig.

DL subframe number n

0 1 2 3 4 5 6 7 8 9

0 6 4 6 4

1 7,6 4 7,6 4

2 8,7,4,6 8,7,4,6

3 7,6,11 6,5 5,4

4 12,8,7,11 6,5,4,7

5 13,12,9,8,7,5,4,11

6 7 7 5 7 7

ACK/NACK on PUSCH or PUCCH in subframe nfor reception of PDSCH insubframe n - k

k for TDD configurartion 0-6

UE Rx Perspective UE Tx Perspective

Multiple ACK/NACK in one subframe:Requieres ACK/NACK bundling (logical AND of codewords) or ACK/NACK multiplexing.

43Marius Pesavento, Willem Mulder, Femto Forum Plenary, June 2010, Reading, UK mimoOn

TDD: Downlink Assignment Index DAIto prevent ACK/NACK errors due to bundling

k for TDD configurartion 0-6 and DAI in DCI format 0 (UL assignments)

DAI indicates the number of subframes with PDSCH receptions and SPS releases detected within n-k and n (k 2 K) that need to be bundeled in the UL ACK/NACK signaling.DAI is used only for TDD

TDD UL/DLConfig.

DL subframe number n

0 1 2 3 4 5 6 7 8 9

0 DAI 6 4 DAI 6 4

1 DAI 6 4 DAI DAI 6 4 DAI

2 4 DAI 4 DAI

3 DAI 4 4 4 DAI DAI

4 4 4 DAI DAI

5 4 DAI

6 DAI DAI 7 7 5 DAI DAI 7 7 DAI

TDD UL/DLConfig.

DL subframe number n

0 1 2 3 4 5 6 7 8 9

0 DAI DAI 6 4 DAI DAI 6 4

1 DAI 7,6 4 DAI DAI 7,6 4 DAI

2 8,7,4,6 DAI 8,7,4,6 DAI

3 DAI 7,6,11 6,5 5,4 DAI DAI

4 12,8,7,11 6,5,4,7 DAI DAI

5 13,12,9,8,7,5,4,11 DAI

6 DAI DAI 7 7 5 DAI DAI 7 7 DAI

k for TDD configurartion 0-6 and DAI in DCI formats 1/1A/1B/1D/2/2A (DL)

0 or 4 or 841,1

3 or 731,0

2 or 620,1

1 or 5 or 910,0

Number of subframes with PDSCH transmission

DAIMSB, LSB

ULDAIV

DLDAIVor

44Marius Pesavento, Willem Mulder, Femto Forum Plenary, June 2010, Reading, UK mimoOn

End of Part 1

Thank you!!!

45Marius Pesavento, Willem Mulder, Femto Forum Plenary, June 2010, Reading, UK mimoOn

Backup slides

46Marius Pesavento, Willem Mulder, Femto Forum Plenary, June 2010, Reading, UK mimoOn

3GPP LTE roadmap

LTE Tutorial part 1LTE BasicsAgenda3G EvolutionLTE TargetsE-UTRA frequency bandsBasic Transmission SchemesFrame Structure Type 1Slot StructureFrame Structure Type 2: TDDFrame Structure Type 2: TDDDwPTS, GP, UpPTS length (in OFDM symbols) Resource BlocksPhysical ChannelsDownlink (DL)Physical ChannelsUplink (UL)PHY SignalsCell-Specific Reference SignalsCell-Specific Reference SignalsDL time-frequency structureUL time-frequency structurePDSCH TxPDSCH RxPUSCH TxPUSCH RxDownlink Control Indicator Format (DCI format)PDCCH processing chainPUCCH processing chain Txall formatsPUCCH processing Rxformat 2, 2a, 2bPUCCH processing Rx format 1PUCCH processing Rxformat 1a, 1bDemodulation reference signals for PUCCH format 2PHICH(DL HARQ)PBCHPRACHPCFICHDL Control FormatRate matching and HARQ processingHARQ timingUE CategoriesUE CategoriesTDD: DL grants and ACK/NACK reportingTDD ACK/NACKRecall: Frame Structure Type 2: TDDTDD: UE ACK/NACK procedure(PUSCH transmission and PHICH reception)DL control issues in TDD DL HARQTDD: Downlink Assignment Index DAIto prevent ACK/NACK errors due to bundlingFoliennummer 44Foliennummer 453GPP LTE roadmap