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UMTS Long Term Evolution LTE
Reiner Stuhlfauth [email protected] Training Centre Rohde & Schwarz, Germany Subject to change - Data without tolerance limits is not binding. R&S© is a registered trademark of Rohde & Schwarz GmbH & Co. KG. Trade names are trademarks of the owners.
2011 ROHDE & SCHWARZ GmbH & Co. KG Test & Measurement Division - Training Center -
This folder may be taken outside ROHDE & SCHWARZ facilities.
ROHDE & SCHWARZ GmbH reserves the copy right to all of any part of these course notes. Permission to produce, publish or copy sections or pages of these notes or to translate them must first be obtained in writing from ROHDE & SCHWARZ GmbH & Co. KG, Training Center, Mhldorfstr. 15, 81671 Munich, Germany
Overview 3GPP UMTS Evolution
Driven by Data Rate and Latency Requirements
WCDMA HSDPA/HSUPA HSPA+ LTE 384 kbps downlink 14 Mbps peak downlink 28 Mbps peak downlink 100 Mbps peak downlink
128 kbps uplink 5.7 Mbps peak uplink 11 Mbps peak uplink 50 Mbps peak uplink
RoundTripTime~150ms RoundTripTime<100ms RoundTripTime <50 ms RoundTripTime~10 ms
3GPP Release 99/4 3GPP Release 5/6 3GPP Release 7 7 3GPP Release 8 8
3GPP Release 99/4 3GPP Release 5/6
2003/4 2005/6 (HSDPA) 2008/9 2009/10 2007/8 (HSUPA)
Approx. year of specification freezing
November 2012 | LTE Introduction | 3
Overview 3GPP UMTS evolution
HSDPA/ LTE and LTE- WCDMA HSPA+ WCDMA HSUPA HSPA+ advanced
3GPP 3GPP Study 3GPP Release 99/4 3GPP Release 7 3GPP Release 5/6 3GPP Release 8 release Item initiated
App. year of 2005/6 (HSDPA) 2008/2009 2003/4 2010 network rollout 2007/8 (HSUPA)
Downlink LTE: 150 Mbps* (peak) 100 Mbps high mobility HSPA+: 42 Mbps (peak) 384 kbps (typ.) 28 Mbps (peak) 14 Mbps (peak) data rate 1 Gbps low mobility
Uplink LTE: 75 Mbps (peak) 128 kbps (typ.) 5.7 Mbps (peak) 11 Mbps (peak) data rate
Round LTE: ~10 ms < 50 ms < 100 ms ~ 150 ms Trip Time
*based on 2x2 MIMO and 20 MHz operation
November 2012 | LTE Introduction | 4
Overview TD-SCDMA evolution towards LTE TDD
TD-LTE TD-SCDMA HSDPA HSUPA
HSPA+
3GPP release 3GPP Release 4 3GPP Release 5 3GPP Release 7 3GPP Release 8
Downlink 384/128 kbps (typ.) 2.8 Mbps (peak) 2.8 Mbps (peak)* LTE:100 Mbps(req.)
data rate
Uplink data rate 128 kbps (typ.) 128 kbps (typ.) 2.2 Mbs (peak)* LTE: 50 Mbps (req.)
* Higher data rate with the use of multi carrier possible
November 2012 | LTE Introduction | 5
Why LTE? Ensuring Long Term Competitiveness of UMTS
l LTE is the next UMTS evolution step after HSPA and HSPA+.
l LTE is also referred to as EUTRA(N) = Evolved UMTS Terrestrial Radio Access (Network).
l Main targets of LTE:
l Peak data rates of 100 Mbps (downlink) and 50 Mbps (uplink)
l Scalable bandwidths up to 20 MHz
l Reduced latency
l Cost efficiency l Operation in paired (FDD) and unpaired (TDD) spectrum
November 2012 | LTE Introduction | 6
Introduction to UMTS LTE: Key parameters Frequency
UMTS FDD bands and UMTS TDD bands Range
1.4 MHz 3 MHz 5 MHz 10 MHz 15 MHz 20 MHz Channel bandwidth,
6 15 25 50 75 100 1 Resource Resource Resource Resource Resource Resource Resource Block=180 kHz
Blocks Blocks Blocks Blocks Blocks Blocks
Modulation Downlink: QPSK, 16QAM, 64QAM Schemes Uplink: QPSK, 16QAM, 64QAM (optional for handset)
Downlink: OFDMA (Orthogonal Frequency Division Multiple Access) Multiple Access
Uplink: SC-FDMA (Single Carrier Frequency Division Multiple Access)
Downlink: Wide choice of MIMO configuration options for transmit diversity, spatial MIMO
multiplexing, and cyclic delay diversity (max. 4 antennas at base station and handset) technology Uplink: Multi user collaborative MIMO
Downlink: 150 Mbps (UE category 4, 2x2 MIMO, 20 MHz) Peak Data Rate 300 Mbps (UE category 5, 4x4 MIMO, 20 MHz)
Uplink: 75 Mbps (20 MHz)
LTE/LTE-A Frequency Bands (FDD) Uplink (UL) operating band Downlink (DL) operating band E - UTRA
BS receive UE transmit BS transmit UE receive Operating Duplex Mode Band
1 1920 MHz - 1980 MHz 2110 MHz - 2170 MHz FDD
2 1850 MHz - 1910 MHz 1930 MHz - 1990 MHz FDD
3 1710 MHz - 1785 MHz 1805 MHz - 1880 MHz FDD
4 1710 MHz - 1755 MHz 2110 MHz - 2155 MHz FDD
5 824 MHz - 849 MHz 869 MHz - 894MHz FDD
6 830 MHz - 840 MHz 875 MHz - 885 MHz FDD
7 2500 MHz - 2570 MHz 2620 MHz - 2690 MHz FDD
8 880 MHz - 915 MHz 925 MHz - 960 MHz FDD
9 1749.9 MHz - 1784.9 MHz 1844.9 MHz - 1879.9 MHz FDD
10 1710 MHz - 1770 MHz 2110 MHz - 2170 MHz FDD
11 1427.9 MHz - 1452.9 MHz 1475.9 MHz - 1500.9 MHz FDD
12 698 MHz - 716 MHz 728 MHz - 746 MHz FDD
13 777 MHz - 787 MHz 746 MHz - 756 MHz FDD
14 788 MHz - 798 MHz 758 MHz - 768 MHz FDD
17 704 MHz - 716 MHz 734 MHz - 746 MHz FDD
18 815 MHz - 830 MHz 860 MHz - 875 MHz FDD
19 830 MHz - 845 MHz 875 MHz - 890 MHz FDD
20 832 MHz - 862 MHz 791 MHz - 821 MHz FDD
21 1447.9 MHz - 1462.9 MHz 1495.9 MHz - 1510.9 MHz FDD
22 3410 MHz - 3500 MHz 3510 MHz - 3600 MHz FDD
November 2012 | LTE Introduction | 13
LTE/LTE-A Frequency Bands (TDD)
Uplink (UL) operating band Downlink (DL) operating band E - UTRA
BS receive UE transmit BS transmit UE receive Operating Duplex Mode
Band
33 1900 MHz - 1920 MHz 1900 MHz - 1920 MHz TDD
34 2010 MHz - 2025 MHz 2010 MHz - 2025 MHz TDD
35 1850 MHz - 1910 MHz 1850 MHz - 1910 MHz TDD
36 1930 MHz - 1990 MHz 1930 MHz - 1990 MHz TDD
37 1910 MHz - 1930 MHz 1910 MHz - 1930 MHz TDD
38 2570 MHz - 2620 MHz 2570 MHz - 2620 MHz TDD
39 1880 MHz - 1920 MHz 1880 MHz - 1920 MHz TDD
40 2300 MHz - 2400 MHz 2300 MHz - 2400 MHz TDD
3400 MHz - 3400 MHz - 41 TDD
3600MHz 3600MHz
November 2012 | LTE Introduction | 14
LTE frequency allocation - FDD
= Uplink frequency = Downlink frequency
November 2012 | LTE Introduction | 16
Orthogonal Frequency Division Multiple Access
the modulation scheme for LTE in downlink and OFDM is uplink (as reference)
Some technical explanation about our physical base: radio link aspects
November 2012 | LTE Introduction | 17
What does it mean to use the radio channel? Using the radio channel means to deal with aspects like:
C
A
D
B Receiver Transmitter
MPP
Time variant channel Doppler effect
attenuation Frequency selectivity November 2012 | LTE Introduction | 18
Types of degradation in cellular networks
l Multiple Access Interference (MAI) l Inter cell interference l Intra cell interference l Adjacent channel interference l Co channel interference
l Fading l Large scale fading
- Known as log-normal fading or shadowing
- Depends on distance between transmitter and receiver l Small scale fading - due to Multipath propagation and Doppler shift
- Depends on signal bandwidth, relative velocity, environment
November 2012 | LTE Introduction | 19
What is OFDM?
Single carrier transmission, e.g. WCDMA
Broadband, e.g. 5MHz for WCDMA
Orthogonal Frequency Division Multiplex
Several 100 subcarriers, with x kHz spacing
November 2012 | LTE Introduction | 27
OFDM signal generation e.g. QPSK
00 11 01 10 01 01 11 01 > .
h*(sin jwt + cos jwt )
h*(sin jwt + cos jwt )
=> S h * (sin.. + cos > )
Frequency
time
OFDM symbol duration ? t November 2012 | LTE Introduction | 29
OFDM Symbol
OFDM symbol duration ? t
November 2012 | LTE Introduction | 33
Inter-Carrier-Interference (ICI) 10
0
-10
-20
-30 xx
S -40
-50
-60
-70 -1 -0.5 0 0.5 1
f -1 f 0 f 1 f f -2 f 2
ICI Problem of MC - FDM
Overlapp of neighbouring subcarriers
Inter Carrier Interference (ICI).
Solution
"Special" transmit g s (t) and receive filter g r (t) and frequencies f k allows orthogonal subcarrier
Orthogonal Frequency Division Multiplex (OFDM)
November 2012 | LTE Introduction | 34
Rectangular Pulse
A(f)
Convolution sin(x)/x
t f
? t
? f time frequency
November 2012 | LTE Introduction | 35
Orthogonality
Orthogonality condition: ? f = 1/ ? t
? f
November 2012 | LTE Introduction | 36
ISI and ICI due to channel
Symbol l l-1 l+1
L L
Receiver DFT n Window
Delay spread
L L
L L L L
fade out (ISI) fade in (ISI)
November 2012 | LTE Introduction | 37
ISI and ICI: Guard Interval
Symbol l l-1 l+1
L L
T G > Delay Spread
Receiver DFT n Window
Delay spread
L L
L L L L
Guard Interval guarantees the suppression of ISI!
November 2012 | LTE Introduction | 38
Guard Interval as Cyclic Prefix Cyclic Prefix
Symbol l l-1 l+1
L L
T G > Delay Spread
Receiver DFT n Window
Delay spread
L L
L L L L
Cyclic Prefix guarantees the suppression of ISI and ICI!
November 2012 | LTE Introduction | 39
Synchronisation
Cyclic Prefix l + 1 OFDM Symbol : l 1 l
CP CP CP CP
Metric
- Search window
~ n
November 2012 | LTE Introduction | 40
DL CP-OFDM signal generation chain
l OFDM signal generation is based on Inverse Fast Fourier Transform (IFFT) operation on transmitter side:
N Useful Data QAM OFDM Cyclic prefix 1:N N:1 symbol IFFT OFDM source Modulator symbols insertion streams symbols
Frequency Domain Time Domain
l On receiver side, an FFT operation will be used.
November 2012 | LTE Introduction | 41
OFDM: Pros and Cons
Pros:
scalable data rate
efficient use of the available bandwidth
robust against fading
1-tap equalization in frequency domain
Cons:
high crest factor or PAPR. Peak to average power ratio
very sensitive to phase noise, frequency- and clock-offset
guard intervals necessary (ISI, ICI) reduced data rate
November 2012 | LTE Introduction | 42
MIMO Multiple Input Multiple Output Antennas
November 2012 | LTE Introduction | 43
MIMO is defined by the number of Rx / Tx Antennas and not by the Mode which is supported
Mode
SISO Typical todays wireless Communication System 1 1
Single Input Single Output
Transmit Diversity
MISO l Maximum Ratio Combining (MRC) 1 1
l Matrix A also known as STC Multiple Input Single Output M l Space Time / Frequency Coding (STC / SFC)
Receive Diversity
SIMO l Maximum Ratio Combining (MRC) 1 1
Single Input Multiple Output Receive / Transmit Diversity M
Spatial Multiplexing (SM) also known as: l Space Division Multiplex (SDM) l
MIMO True MIMO 1 1 l Single User MIMO (SU-MIMO)
l Matrix B Multiple Input Multiple Output M M Space Division Multiple Access (SDMA) also known as: l Multi User MIMO (MU MIMO) l Virtual MIMO l Collaborative MIMO Definition is seen from Channel Beamforming Multiple In = Multiple Transmit Antennas
November 2012 | LTE Introduction | 44
MIMO modes in LTE
-Spatial Multiplexing -Tx diversity
-Multi-User MIMO -Beamforming -Rx diversity
Increased Increased
Throughput per Throughput at
UE Better S/N Node B
November 2012 | LTE Introduction | 45
RX Diversity
Maximum Ratio Combining depends on different fading of the
two received signals. In other words decorrelated fading channels
November 2012 | LTE Introduction | 46
TX Diversity: Space Time Coding
Fading on the air interface
data The same signal is transmitted at differnet
antennas space Aim: increase of S/N ratio
increase of throughput * s 1 s 2 Alamouti Coding = diversity gain
time approaches * s 2 s 1
RX diversity gain with MRRC! Alamouti Coding -> benefit for mobile communications
November 2012 | LTE Introduction | 47
MIMO Spatial Multiplexing C=B*T*ld(1+S/N)
SISO: Single Input Single Output
Higher capacity without additional spectrum! MIMO: S
T B ld ( 1 + ) ?
min( N T , N R )
i
N i i = 1
Multiple Input i
Multiple Output
Increasing capacity per cell
November 2012 | LTE Introduction | 48
The MIMO promise l Channel capacity grows linearly with antennas
Max Capacity ~ min(N TX , N RX )
l Assumptions l Perfect channel knowledge l Spatially uncorrelated fading
l Reality l Imperfect channel knowledge l Correlation ? 0 and rather unknown
November 2012 | LTE Introduction | 49
Spatial Multiplexing
Coding Fading on the air interface
data
data
<200% 200% 100% Throughput:
Spatial Multiplexing: We increase the throughput but we also increase the interference!
November 2012 | LTE Introduction | 50
Introduction - Channel Model II
Correlation of propagation
h 11
pathes h 21
s 1 r 1 h M
R1
h 12
estimates s 2 h 22 r 2
Transmitter Receiver h M R2
h 1M h 2M
T T
N Tx N Rx h M sN Tx r NRx
antennas RMT
antennas
s r H
Rank indicator
Capacity ~ min(N TX , N RX ) max. possible rank!
But effective rank depends on channel, i.e. the correlation situation of H
November 2012 | LTE Introduction | 51
Spatial Multiplexing prerequisites Decorrelation is achieved by:
difficult l Decorrelated data content on each spatial stream
l Large antenna spacing Channel condition
l Environment with a lot of scatters near the antenna (e.g. MS or indoor operation, but not BS)
Technical l Precoding assist
But, also possible that decorrelation
l Cyclic Delay Diversity is not given
November 2012 | LTE Introduction | 52
MIMO: channel interference + precoding MIMO channel models: different ways to combat against
channel impact:
I.: Receiver cancels impact of channel
II.: Precoding by using codebook. Transmitter assists receiver in cancellation of channel impact
III.: Precoding at transmitter side to cancel channel impact
November 2012 | LTE Introduction | 53
MIMO - work shift to transmitter
Channel Receiver Transmitter
November 2012 | LTE Introduction | 57
MIMO precoding precoding Ant1 Ant2 t
+ 1
2 S 1
t +
1 -1 1 precoding
S =0
t t
November 2012 | LTE Introduction | 59
MIMO - codebook based precoding Precoding codebook
noise
s r + R A H
receiver transmitter channel
Precoding Matrix Identifier, PMI
Codebook based precoding creates some kind of "beamforming lite"
November 2012 | LTE Introduction | 60
MIMO: avoid inter-channel interference - future outlook
e.g. linear precoding: Y=H*F*S+V V 1,k
+ S Link adaptation H Space time Transmitter
receiver F
+ x k y k
V M,k
Feedback about H
Idea: F adapts transmitted signal to current channel conditions
November 2012 | LTE Introduction | 61
MAS: "Dirty Paper" Coding - future outlook l Multiple Antenna Signal Processing: "Known Interference"
l Is like NO interference
l Analogy to writing on "dirty paper" by changing ink color accordingly
"Known "Known "Known "Known Interference Interference Interference Interference
is No is No is No is No Interference" Interference" Interference" Interference"
November 2012 | LTE Introduction | 62
Spatial Multiplexing
Codeword Fading on the air interface
data
Codeword data
Spatial Multiplexing: We like to distinguish the 2 useful Propagation passes: How to do that? => one idea is SVD
November 2012 | LTE Introduction | 63
Idea of Singular Value Decomposition MIMO s1 r1
know
r= H s+n s2 r2
channel H Singular Value Decomposition
~ ~ s1 r1 SISO
wanted ~ ~ s2 r2 ~ = D s + n ~ ~ r
channel D
November 2012 | LTE Introduction | 64
MIMO transmission modes Transmission mode 2
Transmit diversity PDCCH indication via
DCI format 1 or 1A
Codeword is sent redundantly over several
streams 1 codeword
PDSCH transmission via 2 Or 4 antenna ports No feedback regarding
antenna selection or precoding needed
November 2012 | LTE Introduction | 72
MIMO transmission modes
Closed loop MIMO = UE feedback needed regarding
Transmission mode 6 precoding and antenna Transmit diversity or Closed loop selection spatial multiplexing with 1 layer
PDCCH indication via DCI format 1A
1 codeword PDSCH transmission via 2 or 4 antenna ports
PDCCH indication via DCI format 1B
Codeword is split into 1 streams, both streams have codeword
to be combined
feedback
PDSCH spatial multiplexing, only 1 codeword
November 2012 | LTE Introduction | 76
Beamforming
Closed loop precoded Adaptive Beamforming beamforming
Classic way Kind of MISO with channel
knowledge at transmitter Antenna weights to adjust beam
Precoding based on feedback Directional characteristics
No specific antenna Specific antenna array geometrie array geometrie
Dedicated pilots required Common pilots are sufficient
November 2012 | LTE Introduction | 78
Spatial multiplexing vs beamforming
Spatial multiplexing increases throughput, but looses coverage
November 2012 | LTE Introduction | 79
Spatial multiplexing vs beamforming
Beamforming increases coverage
November 2012 | LTE Introduction | 80
System architecture evolution , SAE + IP multimedia subsystem , IMS
November 2012 | LTE Introduction | 81
3 GPP System Architecture Evolution Signaling interfaces
Data transport interfaces RAN
Access PDN directly or via IMS
MME PDN UE Evolved nodeB
IMS S-GW P-GW
PSTN Evolved Packet Core external
IMS to control All interfaces are packet switched access + data
transfer
November 2012 | LTE Introduction | 82
LTE: EPS Bearer
E-UTRAN EPC Internet
UE eNB S-GW P-GW Peer Entity
End-to-end Service
EPS Bearer External Bearer
Radio Bearer S1 Bearer S5/S8 Bearer
Radio S1 S5/S8 Gi
November 2012 | LTE Introduction | 83
What is IMS? A high level summary l The success of the internet, using the Internet Protocol (IP) for
providing voice, data and media has been the catalyst for the convergence of industries, services, networks and business models, l IP provides a platform for network convergence enabling a
service provider to offer seamless access to any services, How to merge IP anytime, anywhere, and with any device,
and cellular l 3GPP has taken these developments into account world?? with specification of IMS,
l IMS stands for I P M ultimedia S ubsystem, l IMS is a global access-independent and standard-based IP
connectivity and service control architecture that enables various types of multimedia services to end-users using common internet-based protocols,
l Defines an architecture for the convergence of audio, video, data and fixed and mobile networks.
November 2012 | LTE Introduction | 84
IMS: Reference Model (3GPP/3GPP2)
November 2012 | LTE Introduction | 85
IMS simplified structure
November 2012 | LTE Introduction | 86
IMS protocol structure
user plane
Control plane Voice messaging video
SIP/SDP IKE RTP MSRP
UDP / TCP / SCTP
IP / IP sec Layer 3 control
Layer 1/2 Layer 1/2 (other IP CAN)
Mobile com specific protocols IMS specific protocols
November 2012 | LTE Introduction | 87
LTE physical layer aspects
November 2012 | LTE Introduction | 88
Basic OFDM parameter LTE
1 T
F s = N FFT f
N FFT
3 . 84 Mcps 256
f = 2048 N FFT
Coded symbol rate= R
Sub-carrier CP S/P IFFT Mapping insertion
N Data symbols TX
Size-N FFT
November 2012 | LTE Introduction | 89
Cyclic prefix length Normal cyclic prefix length: 1st CP is longer
1 2 3 4 5 6 7
1 slot = 0,5msec Mismatch in time!
1st Cyclic prefix is longer
1 2 3 4 5 6 7 Normal CP
OFDM OFDM OFDM OFDM OFDM OFDM Extended CP CP CP CP CP CP CP Symbol Symbol Symbol Symbol Symbol Symbol
2 different Cyclic prefix lengths are defined
November 2012 | LTE Introduction | 90
Resource block definition
1 slot = 0,5msec
Resource block =6 or 7 symbols In 12 subcarriers
12 subcarriers
Resource element
UL N symb or N symb DL
6 or 7, Depending on cyclic prefix
November 2012 | LTE Introduction | 91
LTE: new physical channels for data and control Physical Control Format Indicator Channel PCFICH:
Indicates Format of PDCCH
Physical Downlink Control Channel PDCCH: Downlink and uplink scheduling decisions
Physical Downlink Shared Channel PDSCH: Downlink data
Physical Hybrid ARQ Indicator Channel PHICH: ACK/NACK for uplink packets
Physical Uplink Shared Channel PUSCH: Uplink data
Physical Uplink Control Channel PUCCH: ACK/NACK for downlink packets, scheduling requests, channel quality info
November 2012 | LTE Introduction | 92
LTE Downlink
OFDMA time-frequency multiplexing
frequency QPSK, 16QAM or 64QAM modulation
UE4 1 resource block =
180 kHz = 12 subcarriers UE5
UE3 UE2
UE6 Subcarrier spacing = 15 kHz time UE1
1 subframe = 1 slot = 0.5 ms = 1 ms= 1 TTI*= *TTI = transmission time interval 7 OFDM symbols** 1 resource block pair ** For normal cyclic prefix duration
November 2012 | LTE Introduction | 93
Adaptive modulation and coding
Transportation block size
FEC User data
Flexible ratio between data and FEC = adaptive coding
November 2012 | LTE Introduction | 97
Channel Coding Performance
November 2012 | LTE Introduction | 98
Automatic repeat request, latency aspects
Transport block size = amount of data bits (excluding redundancy!)
TTI, Transmit Time Interval = time duration for transmitting 1 transport
block
Transport block Round Trip Time
ACK/NACK
Network UE
Immediate acknowledged or non-acknowledged feedback of data transmission
November 2012 | LTE Introduction | 99
HARQ principle: Stop and Wait
? t = Round trip time
Data Data Data Data Data Data Data Data Data Data Tx
ACK/NACK
Demodulate, decode, descramble, Rx FFT operation, check CRC, etc.
process
Processing time for receiver
Described as 1 HARQ process
November 2012 | LTE Introduction | 100
HARQ principle: Multitasking
? t = Round trip time
Data Data Data Data Data Data Data Data Data Data Tx
ACK/NACK
Demodulate, decode, descramble, Rx FFT operation, check CRC, etc.
process ACK/NACK
Processing time for receiver
Demodulate, decode, descramble, Rx FFT operation, check CRC, etc. process
t
Described as 1 HARQ process
November 2012 | LTE Introduction | 101
LTE Round Trip Time RTT
n+4 n+4 n+4
ACK/NACK PDCC
H PHICH
Downlink
HARQ Data Data UL Uplink
t=0 t=1 t=2 t=3 t=4 t=5 t=6 t=7 t=8 t=9 t=0 t=1 t=2 t=3 t=4 t=5
1 frame = 10 subframes
8 HARQ processes RTT = 8 msec
November 2012 | LTE Introduction | 102
HARQ principle: Soft combining l T i is a e am l o h n e co i g
Reception of first transportation block. Unfortunately containing transmission errors
November 2012 | LTE Introduction | 103
HARQ principle: Soft combining
l hi i n x m le f cha n l c ing
Reception of retransmitted transportation block.
Still containing transmission errors
November 2012 | LTE Introduction | 104
HARQ principle: Soft combining 1st transmission with puncturing scheme P1
l T i is a e am l o h n e co i g
2nd transmission with puncturing scheme P2
l hi i n x m le f cha n l c ing
Soft Combining = S of transmission 1 and 2 l Thi is an exam le of channel co ing
Final decoding
l This is an example of channel coding
November 2012 | LTE Introduction | 105
Hybrid ARQ Chase Combining = identical retransmission
Turbo Encoder output (36 bits)
Systematic Bits Parity 1 Parity 2
Transmitted Bit Rate Matching to 16 bits (Puncturing)
Original Transmission Retransmission
Systematic Bits Parity 1 Parity 2
Punctured Bit Chase Combining at receiver
Systematic Bits Parity 1 Parity 2
November 2012 | LTE Introduction | 106
Hybrid ARQ Incremental Redundancy
Turbo Encoder output (36 bits)
Systematic Bits Parity 1 Parity 2
Rate Matching to 16 bits (Puncturing)
Original Transmission Retransmission
Systematic Bits Parity 1 Parity 2
Punctured Bit Incremental Redundancy Combining at receiver
Systematic Bits Parity 1 Parity 2
November 2012 | LTE Introduction | 107
LTE Physical Layer: SC-FDMA in uplink
Single Carrier Frequency Division Multiple
Access
November 2012 | LTE Introduction | 108
LTE Uplink: How to generate an SC-FDMA signal in theory?
Coded symbol rate= R
Sub-carrier CP DFT IFFT Mapping insertion
N TX symbols
Size-N FFT Size-N TX
LTE provides QPSK,16QAM, and 64QAM as uplink modulation schemes
DFT is first applied to block of N TX modulated data symbols to transform them into frequency domain
Sub-carrier mapping allows flexible allocation of signal to available sub-carriers
IFFT and cyclic prefix (CP) insertion as in OFDM
Each subcarrier carries a portion of superposed DFT spread data symbols
Can also be seen as " pre-coded OFDM " or " DFT-spread OFDM "
November 2012 | LTE Introduction | 109
LTE Uplink: How does the SC-FDMA signal look like?
In principle similar to OFDMA, BUT : In OFDMA, each sub-carrier only carries information related to one
specific symbol In SC-FDMA, each sub-carrier contains information of ALL transmitted symbols
November 2012 | LTE Introduction | 110
LTE uplink SC-FDMA time-frequency multiplexing 1 resource block =
180 kHz = 12 subcarriers Subcarrier spacing = 15 kHz
frequency
UE1 UE2 UE3 1 slot = 0.5 ms = 7 SC-FDMA symbols**
1 subframe = 1 ms= 1 TTI*
UE4 UE5 UE6
*TTI = transmission time interval
** For normal cyclic prefix duration
time QPSK, 16QAM or 64QAM modulation
November 2012 | LTE Introduction | 111
LTE Uplink: baseband signal generation
UE specific Scrambling code
Modulation Transform SC-FDMA Resource Scrambling mapper precoder element mapper signal gen.
Mapping on physical 1 stream = Discrete
Ressource, several Fourier Avoid QPSK i.e. subcarriers, Transform constant 16 QAM subcarriers based on sequences 64 QAM not used for Physical
(optional) reference ressource signals blocks
November 2012 | LTE Introduction | 112
LTE Physical Layer:
Reference signals - general aspects
Reference signals in Downlink Reference signals in Uplink
November 2012 | LTE Introduction | 113
LTE Reference signals in UL and DL overview
l i nk U pl own i nk D
Downlink reference signals: Uplink reference signals:
Primary synchronisation signal Random Access Preamble
Secondary synchronisation signal Uplink demodulation reference signal
Cell specific reference signals Sounding reference signal
UE specific reference signals = based on pseudo random bit sequences
= based on Zhadoff-Chu sequences MBMS specific reference signals = only used for special applications
November 2012 | LTE Introduction | 114
Downlink Reference Signals Cell-specific reference signal
R 0 R 0
One antenna port R 0 R 0 freque
ncy
R 0 R 0
R 0 R 0
l = 0 l = 6 l = 0 l = 6
time
Cell specific reference signals Pseudo random bit sequence, based on physical cell ID
Staggered in frequency + time
Distributed over channel bandwidth, always sent
November 2012 | LTE Introduction | 115
MIMO channel estimation due to reference signals
Estimate h 11 h 11
Estimate h 21 h 12
h 21 Estimate h 22 h 22
Estimate h 12
Antenna 1 Antenna 2 November 2012 | LTE Introduction | 116
MIMO in LTE (DL) Reference Symbols / Pilots Antenna 0 R0
R1 Antenna 1 R1 R3 R0 R1 R2 R0
R2 Antenna 2
R3 Antenna 3 R0 R2 R1 R0 R3 R1
12 subcarriers Different Tx antennas
R1 R3 R0 R1 R2 R0 Can be recognized
separately
R0 R2 R1 R0 R3 R1
1 subframe
November 2012 | LTE Introduction | 117
Cell recognition due to physical cell identity Cell specific reference signals depend on N cell ID
ce en refer Cell fic spe pec i cific s eNodeB 2 Cell r efer enc e Physical Cell
eNodeB 1, identity B
Physical Cell Neighbour cells should have different
identity A physical layer cell identities to be distinguished
November 2012 | LTE Introduction | 118
LTE Uplink: Reference Signals
2 different purposes:
1. Uplink channel estimation for uplink coherent demodulation/detection (reference symbol on 4th SC-FDMA symbol)
2. Channel sounding: uplink channel-quality estimation for better scheduling decisions (position tbd)
November 2012 | LTE Introduction | 119
LTE Uplink: Reference Signals when PUSCH
time 0123456 0123456 0123456 0123456
Allocated bandwidth
Example structure
SRS bandwidth configuration frequency
Allocation for PUSCH
Demodulation Reference Signal: Uplink channel estimation for uplink coherent demodulation/detection
Sounding Reference Signal SRS: Channel sounding: uplink channel-quality estimation for better scheduling decisions
November 2012 | LTE Introduction | 120
Sounding reference signal Frequency selective channel
allcoated bandwidth
eNodeB configures the UE when and where to send sounding reference signals
Sounding reference signals in uplink may assist the eNodeB to investigate frequency selectivity
=> Maybe change frequency scheduling
November 2012 | LTE Introduction | 121
Security aspects power control random access Handover aspects
November 2012 | LTE Introduction | 122
LTE security aspects: USIM
Modell of UMTS Subscriber Identity Module, USIM
Statements from TS 33.401:
A Rel-99 or later USIM shall be sufficient for accessing E-UTRAN
Access to E-UTRAN with a 2G SIM shall not be granted.
November 2012 | LTE Introduction | 123
LTE fundamentals Downlink power allocation (1 RB)
For PDSCH power in same PDSCH power to RS, where NO reference Cell-specific PDCCH power symbol as reference signal an signals are present, is UE specific and reference signal depending additional cell specific offset signaled by higher layers as P A ( ? A ). power (RS power), on ? B / ? A
is applied, that is signaled by signaled in SIB Type 2 higher layers as P B ( ? B ).
[Power]
-50.00 dBm
P A = -4.77 dB 2011 ¸ Rohde&Schwarz y] -54.77 dBm c en
qu P B = 3 (-3.98 dB) re
[F -58.75 dBm
r rie ar
bc Su
[Time] 13 11 12 7 9 10 3 5 6 8 1 2 4 0
OFDM symbols
PDSCH - Physical Downlink Shared Channel PDCCH - Physical Downlink Control Channel
November 2012 | LTE Introduction | 126
RACH Preamble (RAP) l RACH Preamble consists of
- CAZAC (Zadoff / Chu Sequence) in TDD/FDD -> orthogonality
- Cyclic Prefix Easy processing in frequency domain
- Guard Time Avoids Interference by no UL-Synchronization
l Different formats for different cell sizes: 0-3 (FDD: 1,2,3 Subframes), 4 (TDD: 1 Symbol)
November 2012 | LTE Introduction | 132
LTE Protocol Architecture
November 2012 | LTE Introduction | 133
EUTRAN stack: protocol layers overview MM ESM User plane
Radio Resource Control RRC
Packet Data Convergence PDCP
Control & Measurements
Radio Bearer
Radio Link Control RLC
Logical channels
Medium Access Control MAC
Transport channels
PHYSICAL LAYER
November 2012 | LTE Introduction | 134
LTE - channels
November 2012 | LTE Introduction | 135
Control plane
Broadcast Paging
RRC connection setup Radio Bearer Control
Mobility functions UE measurement control >
EPS bearer management Authentication
ECM_IDLE mobility handling Paging origination in ECM_IDLE
Security control >
EPS = Evolved packet system RRC = Radio Resource Control
NAS = Non Access Stratum ECM = EPS Connection Management
November 2012 | LTE Introduction | 136
EPS Bearer Service Architecture
E-UTRAN EPC Internet
UE eNB S-GW P-GW Peer Entity
End-to-end Service
EPS Bearer External Bearer
Radio Bearer S1 Bearer S5/S8 Bearer
Radio S1 S5/S8 Gi
November 2012 | LTE Introduction | 137
LTE TDD and FDD mode of operation
November 2012 | LTE Introduction | 138
TDD versus FDD
Downlink
Guard band needed
Uplink
Independent resources in uplink +
downlink
Down- and Uplink
No duplexer Timing and UL/DL needed configuration
needed
November 2012 | LTE Introduction | 139
Paired spectrum not always available -> use TDD mode
November 2012 | LTE Introduction | 140
General comments What is called "Advantages of TDD vs. FDD mode" l Data traffic,
l Asymmetric setting between downlink and uplink possible, depending on the situation,
See interference aspects: UL - DL and inter-cell
l Channel estimation, l Channel characteristic for downlink and uplink same,
In principle yes: But hardware influence!
And: Timing delay UL and DL l Design,
l No duplexer required, simplifies RF design and reduce costs.
But most UEs will be dual- mode: FDD and TDD!
November 2012 | LTE Introduction | 141
LTE TDD mode - overview 7 different UL/DL configurations are defined
Characteristics + differences of UL/DL configurations: Number of subframes dedicated to Tx and Rx Number of Hybrid Automatic Repeat Request, HARQ processes HARQ process timing: time between first transmission and retransmission Scheduling timing: What is the time between PDCCH and PUSCH?
9 different configurations for the "special subframe" are defined
Definition of how long are the DL and UL pilot signals and how much control information can be sent on it. -> also has an impact on cell size
Differences between Uplink and Downlink in TD-LTE
Characteristic of HARQ: Synchronuous or asynchronuous Number of Hybrid Automatic Repeat Request, HARQ processes HARQ process timing: time between first transmission and retransmission
November 2012 | LTE Introduction | 143
LTE TDD: frame structure type 2
Used Always Always Optionally Always for UL used as DL UL DL or DL special
subframe
Subframe# 0 Subframe# 2 Subframe # 3 Subframe#4 Subframe #5 Subframe #7 Subframe #8 Subframe #9
One subframe ,
DwPTS GP UpPTS DwPTS GP UpPTS
DwPTS = PDCCH, P-Sync, Reference symbol, User Data GP = main Guard Period for TDD operation UpPTS = PRACH, sounding reference signal
November 2012 | LTE Introduction | 144
LTE Rel9 / LTE-Rel 10 (= LTE-Advanced) Technology Outlook
Reiner Stuhlfauth [email protected] Training Centre Rohde & Schwarz, Germany
Technology evolution path 2005/2006 2009/2010 2011/2012 2007/2008 2013/2014
EDGE, 200 kHz EDGEevo VAMOS GSM/ DL: 473 kbps DL: 1.9 Mbps Double Speech GPRS UL: 473 kbps UL: 947 kbps Capacity
HSDPA, 5 MHz UMTS HSPA+, R7 HSPA+, R8 HSPA+, R9 HSPA+, R10 DL: 14.4 Mbps DL: 2.0 Mbps DL: 28.0 Mbps DL: 42.0 Mbps DL: 84 Mbps DL: 84 Mbps UL: 2.0 Mbps UL: 2.0 Mbps UL: 11.5 Mbps UL: 11.5 Mbps UL: 23 Mbps UL: 23 Mbps
HSPA, 5 MHz DL: 14.4 Mbps UL: 5.76 Mbps
LTE (4x4), R8+R9, 20MHz LTE-Advanced R10 DL: 300 Mbps DL: 1 Gbps (low mobility) UL: 75 Mbps UL: 500 Mbps
1xEV-DO, Rev. 0 1xEV-DO, Rev. A 1xEV-DO, Rev. B DO-Advanced cdma 1.25 MHz 1.25 MHz 5.0 MHz DL: 32 Mbps and beyond 2000 DL: 2.4 Mbps DL: 3.1 Mbps DL: 14.7 Mbps UL: 12.4 Mbps and beyond
UL: 153 kbps UL: 1.8 Mbps UL: 4.9 Mbps
Fixed WiMAX Mobile WiMAX, 802.16e Advanced Mobile scalable bandwidth Up to 20 MHz WiMAX, 802.16m 1.25 > 28 MHz DL: 75 Mbps (2x2) DL: up to 1 Gbps (low mobility) typical up to 15 Mbps UL: 28 Mbps (1x2) UL: up to 100 Mbps
November 2012 | LTE Introduction | 157
The LTE evolution Rel-9
eICIC enhancements
Relaying Rel-10 In-device
Diverse Data co-existence Application CoMP
Rel-11 Relaying
eICIC eMBMS
SON enhancements enhancements
MIMO 8x8 MIMO 4x4 Carrier Enhanced Aggregation SC-FDMA
Public Warning Positioning Home eNodeB System
Self Organizing Networks eMBMS
UL DL Multi carrier /
DL UL Dual Layer Multi-RAT Beamforming Base Stations
LTE Release 8 FDD / TDD
November 2012 | LTE Introduction | 159
Location based services
The idea is not new, > so what to discuss?
Satellite based services
Location controller
Network based services
Who will do the measurements? The UE or the network? = "assisted"
Who will do the calculation? The UE or the network? = "based"
So what is new? Several ideas are defined and hybrid mode is possible as well,
Various methods can be combined.
November 2012 | LTE Introduction | 169
Measurements for positioning l l UE-assisted measurements. eNB-assisted measurements.
l l Reference Signal Received eNB Rx - Tx time difference. Power l TADV - Timing Advance. (RSRP) and Reference Signal - For positioning Type 1 is of Received Quality (RSRQ). relevance.
l RSTD - Reference Signal Time l AoA - Angle of Arrival. Difference. l UTDOA - Uplink Time Difference
l UE Rx-Tx time difference. of Arrival. TADV (Timing Advance) = eNB Rx-Tx time difference + UE Rx-Tx time difference
Neighbor cell j = (T eNB-RX - T eNB-TX ) + (T UE-RX - T UE-TX )
UL radio frame #i RSTD - Relative time difference
between a subframe received from neighbor cell j and corresponding
subframe from serving cell i: T SubframeRxj - T SubframeRxi DL radio frame #i UL radio frame #i
DL radio frame #i
Serving cell i
eNB Rx-Tx time difference is defined UE Rx-Tx time difference is defined as T eNB-RX - T eNB-TX , where T eNB-RX is
the RSRP, RSRQ are
as T UE-RX - T UE-TX , where T UE-RX is the
received timing of uplink radio frame #i measured on reference received timing of downlink radio frame and T eNB-TX the transmit timing of signals of serving cell i #i from the serving cell i and T UE-TX the downlink radio frame #i.
transmit timing of uplink radio frame #i.
Source: see TS 36.214 Physical Layer measurements for detailed definitions
November 2012 | LTE Introduction | 170
E-UTRAN UE Positioning Architecture l In contrast to GERAN and UTRAN, the E-UTRAN positioning
capabilities are intended to be forward compatible to other access types (e.g. WLAN) and other positioning methods (e.g. RAT uplink measurements).
l Supports user plane solutions, e.g. OMA SUPL 2.0
UE = User Equipment SUPL* = Secure User Plane Location OMA* = Open Mobile Alliance SET = SUPL enabled terminal SLP = SUPL locaiton platform E-SMLC = Evolved Serving Mobile
Location Center MME = Mobility Management Entity RAT = Radio Access Technology
*www.openmobilealliance.org/technical/release_program/supl_v2_0.aspx
Source: 3GPP TS 36.305 November 2012 | LTE Introduction | 171
GNSS positioning methods supported l Autonomeous GNSS
l Assisted GNSS (A-GNSS) l The network assists the UE GNSS receiver to
improve the performance in several aspects: - Reduce UE GNSS start-up and acquisition times
- Increase UE GNSS sensitivity
- Allow UE to consume less handset power
l UE Assisted - UE transmits GNSS measurement results to E-SMLC where the position calculation
takes place
l UE Based - UE performs GNSS measurements and position calculation, suppported by data >
- > assisting the measurements, e.g. with reference time, visible satellite list etc.
- > providing means for position calculation, e.g. reference position, satellite ephemeris, etc.
Source: 3GPP TS 36.305 November 2012 | LTE Introduction | 172
GPS and GLONASS satellite orbits
GPS: 26 Satellites Orbital radius 26560 km
GLONASS: 26 Satellites Orbital radius 25510 km
November 2012 | LTE Introduction | 173
Why is GNSS not sufficent?
Critical scenario Very critical scenario GPS Satellites visibility (Urban)
l Global navigation satellite systems (GNSSs) have restricted performance in certain environments
l Often less than four satellites visible: critical situation for GNSS positioning
support required (Assisted GNSS) alternative required (Mobile radio positioning)
Reference [DLR]
November 2012 | LTE Introduction | 174
Cell ID
l Not new, other definition: Cell of Origin (COO). l UE position is estimated with the knowledge of the geographical
coordinates of its serving eNB. l Position accuracy = One whole cell .
November 2012 | LTE Introduction | 175
Enhanced-Cell ID (E-CID) l UE positioning compared to CID is specified more
accurately using additional UE and/or E UTRAN radio measurements: l E-CID with distance from serving eNB position accuracy: a circle.
- Distance calculated by measuring RSRP / TOA / TADV (RTT).
l E-CID with distances from 3 eNB-s position accuracy: a point. - Distance calculated by measuring RSRP / TOA / TADV (RTT).
l E-CID with Angels of Arrival position accuracy: a point. - AOA are measured for at least 2, better 3 eNB's.
RSRP - Reference Signal Received Power TOA - Time of Arrival
November 2012 | LTE Introduction | 176 TADV - Timing Advance RTT - Round Trip Time
Angle of Arrival (AOA) l AoA = Estimated angle of a UE with respect to a reference
direction (= geographical North), positive in a counter- clockwise direction, as seen from an eNB. l Determined at eNB antenna based
on a received UL signal (SRS). l Measurement at eNB:
l eNB uses antenna array to estimate direction i.e. Angle of Arrival (AOA).
l The larger the array, the more accurate is the estimated AOA.
l eNB reports AOA to LS. l Advantage: No synchronization
between eNB's. l Drawback: costly antenna arrays.
November 2012 | LTE Introduction | 177
OTDOA - Observed Time Difference of Arrival
l UE position is estimated based on measuring TDOA of Positioning Reference Signals (PRS) embedded into overall DL signal received from different eNB's. l Each TDOA measurement describes a hyperbola (line of constant
difference 2a), the two focus points of which (F1, F2) are the two measured eNB-s (PRS sources), and along which the UE may be located.
l UE's position = intersection of hyperbolas for at least 3 pairs of eNB's.
November 2012 | LTE Introduction | 178
Positioning Reference Signals (PRS) for OTDOA Definition
l Cell-specific reference signals (CRS) are not sufficient for positioning, introduction of positioning reference signals (PRS) for antenna port 6. l SINR for synchronization
and reference signals of neighboring cells needs to be at least -6 dB.
l PRS is a pseudo-random QPSK sequence similar to CRS; PRS pattern: l Diagonal pattern with time
varying frequency shift. l PRS mapped around CRS to avoid collisions;
never overlaps with PDCCH; example shows CRS mapping for usage of 4 antenna ports.
November 2012 | LTE Introduction | 179
Observed Time difference
Observed Time Difference of Arrival OTDOA
If network is synchronised, UE can measure time difference
November 2012 | LTE Introduction | 180
Public Warning System (PWS) l Extend the Warning System support of the E-UTRA/E-UTRAN
beyond that introduced in the Release 8 ETWS (Earthquake and Tsunami Warning System) by providing l E-UTRA/E-UTRAN support for multiple parallel Warning Notifications l E-UTRAN support for replacing and canceling a Warning Notification l E-UTRAN support for repeating the Warning Notification with a repetition
period as short as 2 seconds and as long as 24 hours l E-UTRA support for more generic "PWS" indication in the Paging
Indication l The requirement is to extend the UE RRC ETWS broadcast
reception mechanism and the associated paging mechanism to accommodate reception of CMAS (Commercial Mobile Alert System) alerts contained in a CBS message.
l New: TS 22.268 Public Warning System (PWS) Requirements (Release 9)
November 2012 | LTE Introduction | 182
IMT - International Mobile Communication l IMT-2000
l Was the framework for the third Generation mobile communication systems, i.e. 3GPP-UMTS and 3GPP2-C2K
l Focus was on high performance transmission schemes: Link Level Efficiency
l Originally created to harmonize 3G mobile systems and to increase opportunities for worldwide interoperability, the IMT-2000 family of standards now supports four different access technologies, including OFDMA (WiMAX), FDMA, TDMA and CDMA (WCDMA).
l IMT-Advanced l Basis of (really) broadband mobile communication l Focus on System Level Efficiency (e.g. cognitive network
systems) l Vision 2010 - 2015
November 2012 | LTE Introduction | 183
IMT Spectrum
MHz
MHz
Next possible spectrum allocation at WRC 2015! MHz
MHz
November 2012 | LTE Introduction | 184
LTE-Advanced Possible technology features
Relaying Wider bandwidth technology support
Cooperative Enhanced MIMO base stations schemes for DL and UL
Interference management Cognitive radio methods methods
Radio network evolution Further enhanced MBMS
November 2012 | LTE Introduction | 185
Bandwidth extension with Carrier aggregation
November 2012 | LTE Introduction | 186
LTE-Advanced Carrier Aggregation
Contiguous carrier aggregation
Non-contiguous carrier aggregation
November 2012 | LTE Introduction | 187
Aggregation l Contiguous
l Intra-Band
l Non-Contiguous l Intra (Single) -Band
l Inter (Multi) -Band
l Combination
l Up to 5 Rel-8 CC and 100 MHz l Theoretically all CC-BW combinations possible (e.g. 5+10+20 etc)
November 2012 | LTE Introduction | 188
Overview l Carrier Aggregation (CA)
enables to aggregate up to 5 different cells (component carriers CC), so that a maximum system bandwidth of 100 MHz can be supported (LTE-Advanced requirement). l Each CC = Rel-8 autonomous cell
Cell 2 Cell 1 - Backwards compatibility
l CC-Set is UE specific - Registration Primary (P)CC UE1 UE4 UE3 U3 UE4 U2
- Additional BW Secondary (S)CC-s 1-4 l CC2
Network perspective CC1
- Same single RLC-connection for one UE (independent on the CC-s)
UE1 UE2 CC2 CC1
- Many CC (starting at MAC scheduler) UE3
operating the UE l For TDD
- Same UL/DL configuration for all CC-s UE4
November 2012 | LTE Introduction | 189
Deployment scenarios 3) Improve coverage
l #1: Contiguous frequency aggregation - Co-located & Same coverage - Same f
l #2: Discontiguous frequency aggregation - Co-located & Similar coverage - Different f
l #3: Discontiguous frequency aggregation - Co-Located & Different coverage - Different f - Antenna direction for CC2 to cover blank spots
l #4: Remote radio heads - Not co-located - Intelligence in central eNB, radio heads = only transmission
antennas - Cover spots with more traffic - Is the transmission of each radio head within the cell the
same?
l #5:Frequency-selective repeaters - Combination #2 & #4 - Different f - Extend the coverage of the 2nd CC with Relays
November 2012 | LTE Introduction | 190
Physical channel arrangement in downlink
Each component carrier transmits P- Each component SCH and S-SCH, carrier transmits
Like Rel.8 PBCH, Like Rel.8
November 2012 | LTE Introduction | 191
Carrier aggregation: control signals + scheduling
Each CC has its own control channels, like Rel.8
Femto cells: Risk of interference! -> main component carrier will send all control information.
November 2012 | LTE Introduction | 193
LTE-Advanced Carrier Aggregation - Scheduling Non-Contiguous spectrum allocation Contiguous l There is one transport block
RLC transmission buffer (in absence of spatial
Dynamic multiplexing) and one HARQ switching
entity per scheduled component carrier (from the Channel Channel Channel Channel
coding coding coding coding UE perspective), l A UE may receive multiple HARQ HARQ HARQ HARQ
component carriers simultaneously, Data Data Data Data
mod. mod. mod. mod. l Two different approaches are
discussed how to inform the Mapping Mapping Mapping Mapping
UE about the scheduling for each band, e.g. 20 MHz
l Separate PDCCH for each carrier, l Common PDCCH for multiple carrier,
[frequency in MHz]
November 2012 | LTE Introduction | 194
LTE-Advanced Carrier Aggregation - Common and Separate PDCCH?
l Based on RAN WG1#58 the following is up to 3 (4) symbols 1 subframe = 1 ms per subframe
considered being supported for LTE- Time 1 slot = 0.5 ms
Advanced, Frequency l Variant I PDCCH on a component carrier
PDCCH PDCCH PDCCH PDCCH assigns PDSCH resources on the same
PDSCH PDSCH PDSCH PDSCH component carrier (and PUSCH resources on a single linked UL component carrier) - No carrier indicator field, i.e. Rel-8 PDCCH
structure (same coding, same CCE-based PDSCH PDSCH PDSCH PDSCH
resource mapping) and DCI formats PDCCH PDCCH PDCCH PDCCH
l Variant II PDCCH on a component carrier can assign PDSCH or PUSCH resources in one of multiple component carriers using the carrier indicator field
PDSCH PDSCH PDSCH PDSCH - Rel-8 DCI formats extended with 1 to 3 bit carrier PDCCH PDCCH PDCCH PDCCH
indicator field - Reusing Rel-8 PDCCH structure (same coding, same
CCE-based resource mapping)
- Solutions to PCFICH detection errors on the component
Variant (I) Variant (II) Variant (III) PDSCH to be studied Variant (IV) carrier carrying
l In both cases, limiting the number of blind decoding is desirable,
November 2012 | LTE Introduction | 195
Carrier aggregation activation
1. Establish SRB
3. Network Activates PCC =UL + DL
2. UE sends Capability information to the network
4.Network Add secondary CC
November 2012 | LTE Introduction | 196
Carrier aggregation activation - mobility 1. UE has
EUTRAN connection active
2. Secondary CC is added
3. Secondary CC is removed
4. UE and network perform Handover on primary CC
3. Secondary CC is Added in target cell
November 2012 | LTE Introduction | 197
DL MIMO Extension up to 8x8 Codeword to layer mapping for spatial multiplexing
l Max number of transport blocks: 2 Number Number Codeword-to-layer mapping
of code l Number of MCS fields of layers i = 0 , 1 , K M symb layer 1 words l one for each transport block
x ( 0 ) ( i ) = d ( 0 ) ( 2 i ) l ACK/NACK feedback x ( 1 ) ( i ) = d ( 0 ) ( 2 i + 1 )
l 1 bit per transport block for evaluation M symb = M symb 2 = M symb 3 layer ( 0 ) ( 1 ) 5 2
as a baseline x ( i ) = d ( 3 i ) ( 2 ) ( 1 )
x ( 3 ) ( i ) = d ( 1 ) ( 3 i + 1 ) l x ( 4 ) ( i ) = d ( 1 ) ( 3 i + 2 ) Closed-loop precoding supported
l Rely on precoded dedicated x ( 0 ) ( i ) = d ( 0 ) ( 3 i ) x ( 1 ) ( i ) = d ( 0 ) ( 3 i + 1 ) demodulation RS (decision on DL RS) x ( 2 ) ( i ) = d ( 0 ) ( 3 i + 2 ) l M symb = M symb 3 = M symb 3 layer ( 0 ) ( 1 )
Conclusion on the codeword-to- 6 2
x ( i ) = d ( 3 i ) ( 3 ) ( 1 )
layer mapping: x ( 4 ) ( i ) = d ( 1 ) ( 3 i + 1 ) x ( 5 ) ( i ) = d ( 1 ) ( 3 i + 2 ) l DL spatial multiplexing of up to eight x ( 0 ) ( i ) = d ( 0 ) ( 3 i ) layers is considered for LTE-Advanced, x ( 1 ) ( i ) = d ( 0 ) ( 3 i + 1 ) l x ( 2 ) ( i ) = d ( 0 ) ( 3 i + 2 ) Up to 4 layers, reuse LTE codeword-to-
M symb = M symb 3 = M symb 4 layer ( 0 ) ( 1 ) 7 2
layer mapping, x ( 3 ) ( i ) = d ( 1 ) ( 4 i ) x ( 4 ) ( i ) = d ( 1 ) ( 4 i + 1 )
l Above 4 layers mapping - see table x ( 5 ) ( i ) = d ( 1 ) ( 4 i + 2 ) x ( 6 ) ( i ) = d ( 1 ) ( 4 i + 3 )
l Discussion on control signaling x ( 0 ) ( i ) = d ( 0 ) ( 4 i )
details ongoing x ( 1 ) ( i ) = d ( 0 ) ( 4 i + 1 ) x ( 2 ) ( i ) = d ( 0 ) ( 4 i + 2 ) x ( 3 ) ( i ) = d ( 0 ) ( 4 i + 3 ) M symb = M symb 4 = M symb 4 layer ( 0 ) ( 1 )
8 2 x ( 4 ) ( i ) = d ( 1 ) ( 4 i ) x ( 5 ) ( i ) = d ( 1 ) ( 4 i + 1 ) x ( 6 ) ( i ) = d ( 1 ) ( 4 i + 2 ) x ( 7 ) ( i ) = d ( 1 ) ( 4 i + 3 )
November 2012 | LTE Introduction | 198
LTE-Advanced Enhanced uplink SC-FDMA l The uplink
transmission scheme remains SC-FDMA.
l The transmission of the physical uplink shared channel (PUSCH) uses DFT precoding.
l Two enhancements: l Control-data
decoupling l Non-contiguous
data transmission
November 2012 | LTE Introduction | 199
Significant step towards 4G: Relaying ?
Source: TTA's workshop for the future of IMT-Advanced technologies, June 2008
November 2012 | LTE Introduction | 200
Radio Relaying approach
No Improvement of SNR resp. CINR
Source: TTA's workshop for the future of IMT-Advanced technologies, June 2008
November 2012 | LTE Introduction | 201
L1/L2 Relaying approach
Source: TTA's workshop for the future of IMT-Advanced technologies, June 2008
November 2012 | LTE Introduction | 202
LTE-Advanced Coordinated Multipoint Tx/Rx (CoMP)
CoMP
Coordination between cells
November 2012 | LTE Introduction | 203
Present Thrust- Spectrum Efficiency
Momentary snapshot of frequency spectrum allocation
Why not use this part of the spectrum?
l FCC Measurements:- Temporal and geographical variations in the utilization of the assigned spectrum range from 15% to 85%.
November 2012 | LTE Introduction | 204
ODMA - some ideas.
BTS
Mobile devices behave as relay station
November 2012 | LTE Introduction | 205
There will be enough topics
for future trainings
Thank you for your attention!
Comments and questions welcome!
November 2012 | LTE Introduction | 208