03 - lte dimensioning guidelines - outdoor link budget - fdd - ed2.9 - internal
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03 - LTE Dimensioning Guidelines - Outdoor Link Budget - FDD - Ed2.9TRANSCRIPT
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LTE Dimensioning Guidelines Outdoor LinkBudget - FDD
February 2013
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Copyright 2013 by Alcatel-Lucent. All Rights Reserved. About Alcatel-Lucent
Alcatel-Lucent (Euronext Paris and NYSE: ALU) provides solutions that enable service
providers, enterprises and governments worldwide, to deliver voice, data and video
communication services to end-users. As a leader in fixed, mobile and converged broadband
networking, IP technologies, applications, and services, Alcatel-Lucent offers the end-to-
end solutions that enable compelling communications services for people at home, at work
and on the move. For more information, visit Alcatel-Lucent on the Internet.
Notice
The information contained in this document is subject to change without notice. At the
time of publication, it reflects the latest information on Alcatel-Lucents offer, however,
our policy of continuing development may result in improvement or change to the
specifications described.
Trademarks
Alcatel, Lucent Technologies, Alcatel-Lucent and the Alcatel-Lucent logo are trademarks of
Alcatel-Lucent. All other trademarks are the property of their respective owners. Alcatel-
Lucent assumes no responsibility for inaccuracies contained herein.
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History
Changes Date Author
Ed 1.0 1stRelease Dec 2008 Keith Butterworth
Ed 2.0 - Quality review and edits, minor edits to section 4.1 Feb 2009 Keith Butterworth
Ed2.1 Correction to interference margin definition Mar 2009 Keith Butterworth
Ed2.2 Updates to modem performances and active user &
throughput computations. Revamp of parameter naming for air
interface and modem computations. Addition of ACK/NACK link
budget considerations.
Jun 2009 Keith Butterworth
Ed2.3 Updates to the link budget aspects (modification of UL
link budget + addition of revised DL link budget).Nov 2009 Keith Butterworth
Ed2.3 Minor updates and corrections Dec 2009 Keith Butterworth
Ed2.5 Alignment with Ed8.2 link budget (updated SINR
figures, FSS Gain, revised IoT section, rework of DL section,
spatial multiplexing gain)
Ed2.6 Update inline with new dimensioning guidelines
document structure + alignment with changes in Ed8.3.2 of link
budget tool
Feb 2010 Keith Butterworth
Apr 2011 Keith Butterworth
Ed2.7 Minor changes to sections 2.1.4.4, 3.1.3 and 3.1.5.4. Jul 2012 Keith Butterworth
Ed2.8 Minor editorial updates (correction of interference
margin equation). Updates to align with Ed 8.4 of the LKB tool.
Addition of 8bit CQI report over PUCCH link budget.
Ed2.9 Updates to align with Ed8.5 of the LKB tool. Correction
of effective coding rates and other minor corrections.
Sept 2012 Keith Butterworth
Feb 2013 Laurent Demerville
Reviewed by ARFCC(Advanced RF Competence Centre)
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CONTENTS
1 Introduction ....................................................................... 8
2 Uplink Link Budget..............................................................10
2.1 Uplink Link Budget Parameters.................................................112.1.1 UE Characteristics......................................................................12
2.1.2 eNode-B Receiver Sensitivity.........................................................12 2.1.3 Noise Figure.............................................................................12 2.1.4 SINR Performances.....................................................................13 2.1.5 Handling of VoIP on the Uplink ......................................................21 2.1.6 Uplink Explicit Diversity Gains .......................................................23 2.1.7 Interference Margin....................................................................24 2.1.8 Shadowing Margin ......................................................................27 2.1.9 Handoff Gain / Best Server Selection Gain ........................................28 2.1.10 Frequency Selective Scheduling (FSS) Gain ........................................30 2.1.11 Penetration Losses.....................................................................32
2.2 Final MAPL and Cell Range.......................................................322.2.1 Propagation Model .....................................................................33
2.2.2 Site Area.................................................................................34
2.3 Impact of RRH and TMA ..........................................................352.3.1 RRH.......................................................................................35
2.3.2 TMA.......................................................................................35
2.4 Uplink Budget Example...........................................................362.5 Uplink Common Control Channel Considerations ........................... 36
2.5.1 Attach Procedure.......................................................................37
2.5.2 ACK/NACK Feedback...................................................................38 2.5.3 Periodic CQI Reports...................................................................40
3 Downlink Link Budget ..........................................................42
3.1 Downlink Budget Parameters ...................................................43
3.1.1 SINR.......................................................................................43
3.1.2 RSRQ......................................................................................45 3.1.3 Interference Sources ..................................................................46 3.1.4 Geometry................................................................................47 3.1.5 Downlink SINR Performances.........................................................50 3.1.6 Resource Element Distribution.......................................................54 3.1.7 Energy Per Resource Element (EPRE) ...............................................55 3.1.8 Shadowing Margin & Handoff Gain ..................................................56
3.2 Downlink Budget Example .......................................................57
4 Downlink Output Power........................................................59
5 Radio Network Planning .......................................................60
6 Summary ..........................................................................61
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EXECUTIVE SUMMARY
The purpose of this series of dimensioning guidelines is to describe details of Alcatel-Lucents dimensioning rules for the LTE Frequency Division Duplex (FDD) air interface and
eNode-B modem hardware.
A first step of the network design process consists of determining the number of sites
required and deployment feasibility according to the following information:
Site density of any legacy network deployments, Frequency band(s) used by the legacy system(s), if applicable Frequency band(s) used by the LTE system, Bandwidth available for LTE (1.4, 3, 5, 10, 15 or 20 MHz), Requirements in terms of LTE data rates at cell edge (e.g. uplink data edge to be
guaranteed, best effort data, VoIP coverage requirements, etc.).
This initial number of sites is then typically refined by means of a Radio Network Planning
(RNP) study, taking into account site locations, accurate terrain databases and calibrated
propagation models. The figure below illustrates key inputs and outputs of the Alcatel-
Lucent eNode-B dimensioning process:
Coverage Inputs
Area to be covered
Targeted service at cell edge
Indoor penetration level
Traffic Inputs
Number of subscribers
Traffic profile per subscriber
Network Information Incumbent network info
LTE Frequency
LTE Maximum bandwidth
eNodeB Configuration
LTE Bandwidth
MIMO Scheme, Output Power
Coverage Outputs
Cell Range
Legacy Site Reuse
Number of Sites
+ Traffic Inputs
Link Budget
RF Planning
Air Interface
Capacity
Analysis
Traffic Model
ModemDimensioning
Traffic Model
ModemDimensioning
Optional Requirements
Peak Throughput per Site
eNodeB configuration
Number of modems
Modem configuration
- No. connection tokens
- UL & DL Throughput tokens
Coverage Inputs
Area to be covered
Targeted service at cell edge
Indoor penetration level
Traffic Inputs
Number of subscribers
Traffic profile per subscriber
Network Information Incumbent network info
LTE Frequency
LTE Maximum bandwidth
eNodeB Configuration
LTE Bandwidth
MIMO Scheme, Output Power
Coverage Outputs
Cell Range
Legacy Site Reuse
Number of Sites
+ Traffic Inputs
Link Budget
RF Planning
Air Interface
Capacity
Analysis
Traffic Model
ModemDimensioning
Traffic Model
ModemDimensioning
Optional Requirements
Peak Throughput per Site
eNodeB configuration
Number of modems
Modem configuration
- No. connection tokens
- UL & DL Throughput tokens
Figure 1: Alcatel-Lucent Dimensioning Process
As implied in the figure, Alcatel-Lucents process relies on advanced dimensioning rules for
Link Budget Analysis, Air Interface Capacity Analysis, eNode-B Modem Dimensioning, and
Multi-service traffic modeling. The dimensioning process takes into account product
release functionalities and will be updated regularly to follow product evolutions.
As background to further discussion of this process, a qualitative overview of dimensioning
challenges regarding the FDD radio interface and multi-service traffic mix is provided.
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Internal: These rules are implemented in the dedicated LTE tools used by Network
Designers: Alcatel-Lucent LTE Link Budget for FDD and TDD link budget analysis, 9955
and ACCO for radio network planning studies and LTE eNode-B Dimensioning Tool for air
interface capacity and modem dimensioning.
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References
[1] Jakes W.C., Microwave Mobile Communications, IEEE Press, 1994
[2] K.M Rege, S. Nanda, C.F. Weaver, W.C. Peng, Analysis of Fade Margins for Soft
and Hard Handoffs, PIMRC, 1996
[3] K.M Rege, S. Nanda, C.F. Weaver, W.C. Peng, Fade margins for soft and hard
handoffs, Wireless Networks 2, 1996
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1 INTRODUCTION
This document forms one part of a series of network dimensioning guidelines, as detailed inTable 1.
Table 1: Design Topics Covered in the LTE Dimensioning Guidelines Package
Design Topic Document
Deployment Strategy LTE Dimensioning Guidelines - Deployment Strategy
Radio Features LTE Dimensioning Guidelines Radio Features
Outdoor Link Budget LTE Dimensioning Guidelines Outdoor Link Budget
Indoor Link Budget LTE Dimensioning Guidelines Indoor Link Budget
Peak Throughput LTE Dimensioning Guidelines Peak Throughput
Radio Network Planning LTE Dimensioning Guidelines RNP
Air Interface Capacity LTE Dimensioning Guidelines Air Interface Capacity
eNode-B Dimensioning LTE Dimensioning Guidelines Modem
Token & Licensing Dimensioning LTE Dimensioning Guidelines Token & Licensing
S1/X2 Dimensioning LTE Dimensioning Guidelines S1 & X2
Frequency Reuse Considerations LTE Dimensioning Guidelines Frequency Reuse
Diversity & MIMO LTE Dimensioning Guidelines Diversity & MIMO
Traffic Power Control LTE Dimensioning Guidelines Power Control
Traffic Aggregation Modeling LTE Dimensioning Guidelines Traffic Aggregation Modeling
The purpose of this document is to detail the formulation of Alcatel-Lucents LTE link
budget for outdoor macro cellular deployments.
Link budgets are used by Alcatel-Lucent primarily to derive the expected LTE performances
at cell edge on the uplink and compare them with legacy systems in the case of an overlay
of an existing network. This enables the estimation of the proportion of sites that can be
reused (additional constraints such as space for hardware deployment, etc, have to be
considered on top of this) and/or the required number of sites for a Greenfield operator.
Figure 2 illustrates the main inputs and outputs for an LTE link budget coverage analysis.
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Coverage Inputs
Area to be covered
Targeted service at cell edge
Indoor penetration level
Network Information
Incumbent network info
LTE Frequency
LTE Maximum bandwidth
Coverage Outputs
Cell Range
Legacy Site Reuse
Number of Sites
Link Budget
RF Planning
Figure 2: Link Budget Coverage Analysis Inputs/Outputs
Key factors influencing the link budget analysis include the frequency band for LTE
operation, the cell edge performance requirements, and the depth of coverageexpectations.
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2 UPLINK LINK BUDGET
On the uplink, a cell is generally dimensioned by its coverage, the maximum cell range atwhich a mobile station is received with enough quality by the base station.
cell radius
MAPL
RequiredReceived Signal
Max UEtransmit Power
Figure 3: Uplink Link Budget Concept
The signal threshold at which a signal is received with enough quality is called the eNode-B
receive sensitivity. This sensitivity figure will depend upon the:
Data rate targeted at cell edge, Target quality / HARQ operating point (such as Block Error Rate (BLER), maximum
number of retransmissions),
Radio environment conditions (multipath channel, mobile speed), eNode-B receiver characteristics (Noise Figure).
As for 2G and 3G systems, the uplink link budget involves the calculation of the Maximum
Allowable Propagation Loss (or Pathloss), denoted as the MAPL, that can be sustained over
the link between a mobile at cell edge and the eNode-B, while meeting the required
sensitivity level at the eNode-B. As for 2G/3G systems, the uplink link budget calculations
consider all the relevant gains and losses encountered on the link between the mobile and
the eNode-B.
The uplink link budget is formulated such that one service (UL_Guar_Serv) is targeted at
the cell edge, while for more limiting service rates, link budgets are formulated under the
assumption they are not guaranteed at cell edge but at a reduced coverage footprint, as is
illustrated in Figure 4).
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RangeUL_Guar_Serv
128kbps
256kbps
512kbps
UL Rates
Figure 4: Rationale behind the Uplink LKB Formulation
2.1 Uplink Link Budget Parameters
The power, Cj(UL), received at the eNode-B from a mobile (UE) located at cell edge
transmitting with its maximal power, PMaxTX_PUSCH, is given by:
( )dBdBdB
dBdBdBdBdBm
RxRxnPenetratio
Body)Service(ULnPropagatioTxTxHMaxTX_PUSCdBmj(UL)
LossGaininargM
LossRLossesLossGainPC
+
+=
where
dBmPUSCH_MaxTX
P is the maximum transmit power of the UE (see section 2.1.1)
GainTxand LossTx, the gains and losses at the transmitter side such as UE antennagain
GainRx and LossRx represent the gains and losses at the receiver side such as theeNode-B antenna gain and the feeder losses between the eNode-B and the antenna
LossBody is the body losses induced by the user, typically 3dB body losses areconsidered for voice services and 0 dB for data services (handset position is far
from the head when using data services)
MarginPenetration is the losses (in dB) induced by buildings, windows or vehiclesaccording to the penetration coverage objective (deep or light indoor, outdoor)
(see section 2.1.11)
Assuming a Hata-like propagation model, the propagation losses can be expressedaccording to the cell range, LossesPropagation(see section 2.2.1):
)Service(UL102(UL)1(UL))Service(ULnPropagatio RLogKKRLosses dB+=
.
To ensure reliable coverage, the received power at the eNode-B should be higher than the
eNode-B receiver sensitivity (see section 2.1.2):
dBdBdBdBdBm FSSHOShadowingIoTdBmj(UL)GainGainMarginMarginySensitivitC ++
where
MarginIoTis a margin accounting for inter-cell interference (see section 2.1.7) MarginShadowing is a margin that compensates for the slow variability in mean path
loss about that predicted using the propagation model, e.g. Hata (see section 2.1.8)
GainHOis a handoff gain or best server selection gain that models the benefits dueto the ability to reselect to the best available serving site at any given location (see
section 2.1.9)
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GainFSS is a frequency selective scheduling gain that is due to the ability of thescheduler to select best frequency blocks per UE depending on their channel
conditions
For each service to be offered by the operator, this relationship allows computation of the
maximum propagation losses that can be afforded by a mobile located at the cell edge,that is to say the Maximum Allowable Path Loss (MAPL):
dBdBdB
dBdB
dBdBdBdBdBdBm
FSSHOShadowing
IoTdBmnPenetratio
BodyRxRxTxTxHMaxTX_PUSCdBj(UL)
GainGainMargin
MarginySensitivitinargM
LossossLGainossLGainPMAPL
++
++=
2.1.1 UE Characteristics
The maximum transmit power of an LTE UE, PMaxTX_PUSCH, depends on the power class of the
UE. Currently, only one power class is defined in 3GPP TS 36.101:
A 23dBm output power is considered with a 0 dBi antenna gain.
Internal: This is the case in the TS 36.101 version of January 2012. Only one class defined
(Class 3) with 23dBm output power (with 2dB tolerance, but we should not account for
such a tolerance to define the UE output power).
2.1.2 eNode-B Receiver Sensitivity
The sensitivity level can be derived from SINR figures calculated or measured for some
given radio channel conditions (multipath channel, mobile speed) and quality target (e.g.
10-2BLER):
RBRB(UL)theNode_B10PUSCH_dBdBm .W.N.NFLog10SINRySensitivit +=
where:
SINRPUSCH_dBis the signal to interference ratio per Resource Block, required to reacha given PUSCH data rate and quality of service,
FeNode-B.Nth.NRB(UL).WRBis the total thermal noise level seen at the eNode-B receiverwithin the required bandwidth to reach the given data rate, where:
FeNode-Bis the noise figure of the eNode-B receiver, Nthis the thermal noise density (-174dBm/Hz), NRB(UL)is the number of resource blocks (RB) required to reach a given data rate it
can be deduced from link level simulations selecting the best combination (e.g. the
one that requires lowest SNR or lowest number of RB to maximize the capacity),
WRB is the bandwidth used by one LTE Resource Block. One Resource Block iscomposed of 12 subcarriers, each of a 15kHz bandwidth so WRBis equal to 180kHz.
2.1.3 Noise Figure
The Noise Figure of the eNode-B is supplier dependent. Typically the Noise Figures of an
eNode-Bs is 2.5dB.
Internal: Assumed Noise Figures for ALU RRH product variants (September 2010).
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Frequency Band Typical Noise Figure
700 MHz 2.5 dB
800 MHz 2.1 dB
850 MHz 2.1 dB
900 MHz 2.1 dB
1800 MHz 2.0 dB
1900 MHz 2.0 dB
AWS 2.0 dB
2100 MHz 2.0 dB
2600 MHz 2.0 dB
Internal: These figures are dependent on the specific hardware realization and as such
within a given frequency band there will be variation between different product variants.
For precise figures it is recommended to verify the latest figures with LTE Portfolio
Management.
2.1.4 SINR Performances
The SINR figures are derived from link level simulations or better from equipment
measurements (lab or on-field measurements). They depend on the eNode-B equipment
performance, radio conditions (multipath fading profile, mobile speed), receive diversity
configuration (2 branch by default and optionally 4 branch), targeted data rate and quality
of service.
2.1.4.1 Multipath ChannelFor link budget analysis, the most typical UE speed and multipath profiles are considered
according to the type of environment (e.g. dense urban, rural, etc).
In terms of multipath channel, the dense urban, urban or suburban indoor Macrocell
deployment environments are consider to be well characterized by the ITU Vehicular
multipath profile, with mobiles moving at 3km/h and 50km/h for rural environments.
Choosing one multipath channel for a given environment is a modeling assumption. In
reality, in a cell, various multipath conditions exist. A better representation would be to
consider a mix of multipath channel models (even though there is no one unique mix to
represent a typical Macro cell environment that has been agreed across the radio
community). However for a coverage assessment, the worst case model should be
considered. The ITU VehA multipath channel model (2 equivalent main paths) iscorrespondingly a good compromise for a reasonable, worse case, link budget analysis.
For LTE some evolved multipath channel models have been defined such as EVA5Hz or
EPA5Hz. These are an extension of the VehA and PedA models used in UMTS to make them
more suitable for the wider bandwidths encountered with LTE, e.g. >5MHz. Main difference
lies in the definition of a doppler frequency instead of a speed, making the model useable
for different frequency bands. Typical SINR performances used in Alcatel-Lucent link
budgets are for EVehA3 and EVehA50 channel models.
For the purposes of the link budget the underlying assumption is that the UE is at the cell
edge and the main driver is to maximize the coverage.
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2.1.4.2 Number Resource Blocks & Modulation & Coding SchemeFor a given target data rate the required target SINR depends upon (see Figure 5 for some
definitions of the LTE channel structure):
Number Resource Blocks, NRB Modulation & Coding Scheme Index (MCS)
t
f
one
OFDMsymbol
one Subcarrier
Slot (0.5 ms)
Subframe (1 ms)
Slot (0.5 ms)
15 kHz
RB
subframePhysical Resource Block (RB)
= 14 OFDM Symbols x 12Subcarrier
This is the minimum unit ofallocation in LTE
Figure 5: LTE Channel Structure - Some Definitions
The Modulation & Coding Scheme Index (MCS) determines the Modulation Order which in
turn determines the Transport Block Size (TBS) Index to be used (see Table 2).
Table 2: Extract from the Modulation and TBS index table for PUSCH (from 36.213)
MCS Index, IMCS Modulation Order, QM TBS Index, ITBS
0 QPSK 0
1 QPSK 1
2 QPSK 2
3 QPSK 3
For a given MCS Index the Transport Block Size (TBS) is given by Table 3 for different
numbers of resource blocks
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Table 3: Extract from the Transport Block size table (from 36.213)
ITBS NRB= 1 NRB= 2 NRB= 3 NRB= 4 NRB=
0 16 32 56 88
1 24 56 88 144
2 32 72 144 176
3 40 104 176 208
4 56 120 208 256
5 72 144 224 328
6 328 176 256 392
For example, for an MCS Index = 2 and NRB= 3 the corresponding TBS = 144 bits.
2.1.4.3 Hybrid Automatic Repeat request (HARQ)A key characteristic of the LTE air interface is the utilization of HARQ, a combination of
ARQ and channel coding which provides greater robustness against fast fading; these
schemes include incremental redundancy, whereby the code rate is progressively reduced
by transmitting additional parity information with each retransmission.
In LTE, asynchronous adaptive HARQ is used for the downlink, and synchronous HARQ for
the uplink. In the uplink, the retransmissions may be either adaptive or non-adaptive,
depending on whether new signaling of the transmission attributes is provided.
In an adaptive HARQ scheme, transmission attributes such as the modulation and coding
scheme, and transmission resource allocation in the frequency domain, can be changed at
each retransmission in response to variations in the radio channel conditions. In a non-adaptive HARQ scheme, the retransmissions are performed without explicit signaling of new
transmission attributes either by using the same transmission attributes as those of the
previous transmission, or by changing the attributes according to a predefined rule.
Accordingly, adaptive schemes bring more scheduling gain at the expense of increased
signaling overheads.
There are multiple HARQ operating points that can be utilized for an LTE system:
Either, a lower initial BLERwith a correspondingly fewer overall number of HARQtransmissions, resulting in a higher SINR requirement with reduced latency and
better spectral efficiency (e.g. 10% iBLER target for the 1st HARQ transmission)
Or, a higher initial BLERwith a correspondingly greater overall number of HARQtransmissions resulting in a lower SINRrequirement with an increased latencyandpoorer spectral efficiency (e.g. 1% pBLER target after up to 4 HARQ transmissions
iBLER ~50-70%).
The former operating point is currently recommended by Alcatel-Lucent, this corresponds
to a 10% iBLER target for the 1st HARQ transmission.
Internal: Ideally the later operating point is considered at cell edge locations (for which we
perform the link budget) where the objective is to tradeoff spectral efficiency and latency
for an improved SINR and receiver sensitivity. Whereas in locations that are not link budget
constrained, e.g. closer to the eNode-B, the former HARQ operating point is more
appropriate. The current Alcatel-Lucent implementation considers only a 10% iBLER,
eventually a different operating point is likely to be supported, maybe even a dynamic
operating point.
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2.1.4.4 Selection of Optimal MCS Index & NRBFor each targeted uplink data rate there will be an optimal combination of NRB and MCS
Index that will maximize the receiver sensitivity for the relevant HARQ operating point.
Figure 6 provides an example of the selection of the optimal MCS and number of RB, NRB,
for a given target effective data rate. This plot illustrates for the full range of possible MCSindices the corresponding required NRBand the resultant eNode-B receiver sensitivity.
-120.0 dBm
-115.0 dBm
-110.0 dBm
-105.0 dBm
-100.0 dBm
-95.0 dBm
-90.0 dBm
MCS 0 MCS 5 MCS 10 MCS 15 MCS 20 MCS 25 MCS 30
eNode-B
RxSensitivity
1 RB
2 RB
3 RB
4 RB
5 RB
6 RB
7 RB
Required
#
RBf
orServic
Figure 6: Selection of Optimal MCS and NRBfor a target rate of 128kbps with 10% iBLER,EVehA3
From Figure 6 it can be seen that MCS 2 with 3 RBs is optimal, as this provides the best
receiver sensitivity while minimizing utilization of RBs.
Table 4 provides an example of comparison between the 10% iBLER operating point
performance with that for a 1% pBLER operating point, for the same 128kbps target
effective data rate:
Table 4: Example of Different HARQ Operating Points (128kbps)
1% pBLER(high initial BLER)
10% iBLER(low initial BLER)
MCS Index MCS 9 MCS 2
NRB 2 RB 3 RB
TBS Size 296 bits 144 bits
Effective Coding Rate 0.606 0.212
Post HARQ Throughput 128 kbps 128 kbps
Required SINR -0.5 dB 0.2 dB
Receiver Sensitivity (NF=2dB) -116.9 dBm -114.4 dBm
MCS 2 provides the optimal
tradeoff between Rx. Sens
and NRBrequired
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Note: The 1% pBLER HARQ operating point (1% BLER after 4 HARQ Tx) corresponds to an
iBLER (BLER for the 1stHARQ transmission) much greater than 10%.
It can be seen from the example summarized in Table 4, that the same required data rate
can be achieved with different combinations of NRB, MCS Index and number of HARQ
transmissions. The receiver sensitivity comparison below highlights the different coveragefor the same targeted data rate due to the different HARQ operating points:
RBRB(UL)theNode_B10PUSCH_dBdBm .W.N.NF10logSINRySensitivit += Sensitivity1% BLER after 4 HARQ Tx= -0.5 + 10xlog10( 2.0dBxNthx2RBx180kHz ) = -116.9dBm Sensitivity10% BLER after 1 HARQ Tx= 0.2 + 10xlog10( 2.0dBxNthx3RBx180kHz ) = -114.4dBm
While the two solutions require a relatively similar SINR, they utilize a different number of
resource blocks, NRB. The trade-off between the two is a combination of the required
bandwidth (number of resource blocks) and the number of HARQ transmissions versus the
receiver sensitivity.
While the utilization of more HARQ transmissions enhances (reduces) the requiredSINR for an equivalent MCS, it also requires the same air interface resources for alonger period of time (more transmission time intervals).
Utilizing more resource blocks degrades the receiver sensitivity due to an increasednoise bandwidth (180 kHz x number of resource blocks).
Note that the difference between the receiver sensitivities in Table 4 is due to the
difference in the required SINR and the difference in the number of resource blocks.
Figure 7shows an identical analysis to that presented in Figure 6 with the exception that
here an effective data rate of 512kbps is targeted.
-115.0 dBm
-110.0 dBm
-105.0 dBm
-100.0 dBm
-95.0 dBm
-90.0 dBm
MCS 0 MCS 5 MCS 10 MCS 15 MCS 20 MCS 25 MCS 30
eNode-B
Rx
Sensitivity
1 RB
6 RB
11 RB
16 RB
21 RB
26 RB
Required
#
RB
forServic
Figure 7: Selection of Optimal MCS and NRB for a target rate of 512kbps with 10% iBLER,
EVehA3
From Figure 7 it can be seen that now MCS 3 with 10 RBs is optimal as this provides the
best receiver sensitivity while minimizing utilization of RBs.
Table 5 provides a comparison between the 10% iBLER operating point performance with
that for a 1% pBLER operating point, for the same 512kbps target effective data rate:
MCS 3 provides the optimal
tradeoff between Rx. Sens
and NRBrequired
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Table 5: Example of Different HARQ Operating Points (512kbps)
1% pBLER
(high initial BLER)
10% iBLER
(low initial BLER)
MCS IndexMCS 8
MCS 3
NRB 8 RB 10 RB
TBS Size 1096 bits 568 bits
Effective Coding Rate 0.530 0.224
Post HARQ Throughput 512 kbps 512 kbps
Required SINR -0.8 dB 0.2 dB
Receiver Sensitivity (NF=2dB) -111.2 dB -109.2 dB
Making the same comparison of the receiver sensitivity:
RBRB(UL)theNode_B10PUSCH_dBdBm .W.N.NF10logSINRySensitivit += Sensitivity1% BLER after 4 HARQ Tx= -0.8 + 10xlog10( 2.0dBxNthx8RBx180kHz ) = -111.2dBm Sensitivity10% BLER after 1 HARQ Tx= 0.2 + 10xlog10( 2.0dBxNthx10RBx180kHz ) = -109.2dBm
Here the difference between the receiver sensitivities is due to the combination of the
differences in the required SINR and in the required bandwidth (dictated by the number of
resource blocks, NRB). Thus it is important when comparing the required SINR for two
services to consider also the required number of resource blocks.
2.1.4.5 Typical SINR PerformancesBased on link level simulations, for a HARQ operating point that targets 1% pBLER, the
optimal combination of NRB, MCS Index and the corresponding SINR target for the typical
data rates considered in Alcatel-Lucent uplink link budgets are summarized in Table 6 andTable 7 for EVehA3 and EVehA50 channel conditions respectively with 2-way Rx Diversity.
Table 6: Typical Rates Considered in Uplink Link Budget for EVehA3 channel conditions
@ 700MHz with 2.5dB Noise Figure, 1% post HARQ BLER
Post HARQ Peak Tput 9.3 kbps 64 kbps 128 kbps 256 kbps 512 kbps 1000 kbps 2000 kbps
MCS Index MCS 0 MCS 9 MCS 9 MCS 8 MCS 8 MCS 6 MCS 4
Modulation QPSK QPSK QPSK QPSK QPSK QPSK QPSK
NRB(UL) 1 RB 1 RB 2 RB 4 RB 8 RB 20 RB 45 RB
HARQ Operating Point 1% pBLER 1% pBLER 1% pBLER 1% pBLER 1% pBLER 1% pBLER 1% pBLER
Initial BLER 52.3% 78.9% 79.5% 75.2% 78.8% 80.4% 51.3%
TBS Size 16 bits 136 bits 296 bits 536 bits 1096 bits 2088 bits 3240 bits
Effective Coding Rate 0.152 0.606 0.606 0.53 0.530 0.400 0.275
Average # HARQ Tx 1.71 2.13 2.31 2.09 2.14 2.09 1.62
SINR Target -5.9 dB -0.5 dB -0.5 dB -0.9 dB -1.1 dB -2.5 dB -3.7 dB
Rx Sensitivity -124.8 dBm -119.4 dBm -116.4 dBm -113.9 dBm -111.0 dBm -108.5 dBm -106.1 dBm
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Table 7: Typical Rates Considered in Uplink Link Budget for EVehA50 channel conditions
@ 700MHz with 2.5dB Noise Figure, 1% post HARQ BLER
Post HARQ Peak Tput 7.5 kbps 64 kbps 128 kbps 256 kbps 512 kbps 1000 kbps 2000 kbps
MCS Index MCS 0 MCS 6 MCS 7 MCS 10 MCS 10 MCS 10 MCS 10Modulation QPSK QPSK QPSK QPSK QPSK QPSK QPSK
NRB(UL) 1 RB 2 RB 3 RB 4 RB 8 RB 16 RB 32 RB
HARQ Operating Point 1% pBLER 1% pBLER 1% pBLER 1% pBLER 1% pBLER 1% pBLER 1% pBLER
Initial BLER 74.2% 86.2% 88.6% 95.6% 95.6% 95.6% 95.6%
TBS Size 16 bits 176 bits 328 bits 680 bits 1384 bits 2792 bits 5736 bits
Effective Coding Rate 0.152 0.379 0.444 0.667 0.667 0.667 0.682
Average # HARQ Tx 2.12 2.75 2.56 2.66 2.70 2.79 2.87
SINR Target -6.4 dB -2.5 dB -2.2 dB -0.6 dB -0.9 dB -1.4 dB -1.7 dB
Rx Sensitivity -125.3 dBm -118.5 dBm -116.3 dBm -113.6 dBm -110.8 dBm -108.3 dBm -105.5 dBm
Internal: If quoting SINR performances to customers the 10% iBLER figures (Table 8 and
Table 9) should be presented (as they are more representative of current product
characteristics) in preference to the 1% pBLER figures (Table 6 and Table 7).
The above SINR figures have been derived from link level simulations which assume ideal
scheduling and link adaptation, the reality in the field will not be as good. To compensate
for such ideal assumptions, there are currently two key elements to the margins
incorporated into in the SINR performances used in uplink budgets today:
Implementation Margin: to account for the assumptions implicit in the link levelsimulations used to derive the SINR performances
o Currently considered to be ~1dBo No variability is assumed for different environments or UE mobility
conditions
o Will be tuned based on SINR measurements (not yet performed) ACK/NACK Margin: to account for the puncturing of ACK/NACK onto the PUSCH
o A 1dB margin is applied for VoIP services and 0.5dB for higher datathroughputs
The SINR performances quoted in Table 6, Table 7 and subsequently in Table 8 and Table 9
account for the above mentioned implementation and ACK/NACK margins.
Table 8 and Table 9 summarize the same for a 10% iBLER HARQ operating point.
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Table 8: Typical Rates Considered in Uplink Link Budget (for EVehA3 channel conditions
@ 700MHz with 2.5dB Noise Figure, 10% iBLER)
Post HARQ Peak Tput 14.5 kbps 64 kbps 128 kbps 256 kbps 512 kbps 1000 kbps 2000 kbps
MCS Index MCS 0 MCS 5 MCS 2 MCS 5 MCS 3 MCS 4 MCS 5
Modulation QPSK QPSK QPSK QPSK QPSK QPSK QPSK
NRB(UL) 1 RB 1 RB 3 RB 4 RB 10 RB 16 RB 25 RB
HARQ Operating Point 10% iBLER 10% iBLER 10% iBLER 10% iBLER 10% iBLER 10% iBLER 10% iBLER
TBS Size 16 bits 72 bits 144 bits 328 bits 568 bits 1128 bits 2216 bits
Effective Coding Rate 0.152 0.364 0.212 0.333 0.224 0.273 0.339
Average # HARQ Tx 1.1 1.1 1.1 1.1 1.1 1.1 1.1
SINR Target (EVehA3) -1.2 dB 2.8 dB 0.2 dB 1.9 dB 0.2 dB 0.4 dB 0.9 dB
Rx Sensitivity (EVehA3) -120.2 dBm -116.1 dBm -113.9 dBm -111.0 dBm -108.7 dBm -106.5 dBm -104.1 dBm
Table 9: Typical Rates Considered in Uplink Link Budget (for EVehA50 channel
conditions @ 700MHz with 2.5dB Noise Figure, 10% iBLER)
Post HARQ Peak Tput 14.5 kbps 64 kbps 128 kbps 256 kbps 512 kbps 1000 kbps 2000 kbps
MCS Index MCS 0 MCS 5 MCS 2 MCS 5 MCS 3 MCS 4 MCS 5
Modulation QPSK QPSK QPSK QPSK QPSK QPSK QPSK
NRB(UL) 1 RB 1 RB 3 RB 4 RB 10 RB 16 RB 25 RB
HARQ Operating Point 10% iBLER 10% iBLER 10% iBLER 10% iBLER 10% iBLER 10% iBLER 10% iBLER
TBS Size 16 bits 72 bits 144 bits 328 bits 668 bits 1128 bits 2216 bits
Effective Coding Rate 0.152 0.364 0.212 0.333 0.224 0.273 0.339
Average # HARQ Tx 1.1 1.1 1.1 1.1 1.1 1.1 1.1
SINR Target (EVehA3) -0.9 dB 3.2 dB 0.5 dB 2.4 dB 0.7 dB 1.1 dB 1.5 dB
Rx Sensitivity (EVehA3) -119.9 dBm -115.7 dBm -113.7 dBm -110.6 dBm -108.2 dBm -105.8 dBm -103.5 dBm
Figure 8 illustrates the receiver sensitivity figures quoted in Table 6, Table 7, Table 8 and
Table 9 for 1%pBLER and 10% iBLER HARQ operating points and EVehA3 and EVehA50 km/h
channel conditions.
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-125 dBm
-120 dBm
-115 dBm
-110 dBm
-105 dBm
10 kbps 100 kbps 1000 kbps
Uplink Average Effective Throughput
ReceiverSensitivity
EVehA 3km/h - 10% iBLER
EVehA 50km/h - 10% iBLER
EVehA 3km/h - 1% pBLER
EVehA 50km/h - 1% pBLER
Figure 8: Receiver Sensitivity for Typical Rates Considered in Uplink Link Budget (for
EVehA3 & EVehA50 channel conditions @ 700MHz with 2.5dB Noise Figure, 10% iBLER
and 1% pBLER)
2.1.5 Handling of VoIP on the Uplink
For VoIP, various approaches (L2 segmentation and TTI bundling) were discussed at 3GPP to
offer good coverage performances of VoIP (see Figure 9). TTI bundling was adopted in 3GPP
Rel8 (36.321).
With TTI bundling, as opposed to RLC Segmentation, larger transport blocks are used.
Relying on incremental redundancy, HARQ Transmissions are performed in consecutive TTIs
without waiting for HARQ feedback. The HARQ receiver accumulates the received energy of
all transmissions and responds with HARQ feedback only once after the entire bundle has
been received and evaluated.
RLC Segmentation 4ms TTI Bundling
Figure 9: RLC Segmentation and 4ms TTI Bundling Operating Modes
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2.1.5.1 VoIP and TTI Bundling No segmentation of VoIP packets required Enhances link budget compared to transmission of a single packet by supporting
more HARQ transmissions in short time period
Not supported in initial UEs and product Otherwise known as VoIP with QoS
The VoIP packet size for an AMR 12.2 VoIP codec, after accounting for RLC and MAC
overheads, is ~328 bits. The VoIP codec generates such packets with ~20ms periodicity.
With 4ms TTI bundling each 328 bit VoIP packet is sent in 4 consecutive TTIs with 4
different redundancy variants (think of this as doing 4 HARQ transmissions in successive
TTIs). These four transmissions can be sent up to a maximum of 4 times and on average 2
times.
For each TTI, MCS Index 6 is utilized with a single RB. This yields a TBS (Transport Block
Size) of 328 bits (MCS 6 & 1 RB is a special combination created especially for VoIP
services). The average effective air interface rate for active transmission for an AMR 12.2
VoIP service over the air interface is 328 bits / 4 successive TTIs / 2 average transmissions =41 kbps, with the maximum of 4 transmissions this drops to 20.5kbps. However, if we
average the codec payload of 328 bits over the 20ms periodicity, the average throughput is
328 bits / 20ms = 16.4 kbps. Table 10 summarizes the VoIP with TTI bundling performance
characteristics that are considered in UL budgets:
Table 10: VoIP with TTI Bundling (1% pBLER target, 2dB NF)
AMR 12.2
Nominal Codec Rate 12.2 kbps
VoIP Packet Size (with overheads) 328 bits
MCS / NRB/ SINR (EVehA3)Rx Sensitivity
MCS 6 / 1 RB / -3.4 dB-122.9 dBm
MCS / NRB/ SINR (EVehA50)
Rx Sensitivity
MCS 6 / 1 RB / -2.9 dB
-122.4 dBm
2.1.5.2 VoIP and RLC Segmentation Segments VoIP packets into multiple smaller segments Enhances link budget compared to transmission of a single packet as the smaller
segments result in a more favorable required MCS and NRB
Substantially higher overheads in terms of required grants and signaling Otherwise known as Over the Top best effort VoIP Very poor link budget without substantial levels of segmentation
There are a wide range of possible VoIP codecs that could be used for such solutions, e.g.
G711 (64kbps) and G729 (8kbps), in fact it is possible to use RLC segmentation with an AMR
12.2 VoIP codec. Table 11 provides a summary of the required TBS size for, varying levels of
segmentation for G.729 and G.711 VoIP codecs and IPv4 and IPv6.
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Table 11: Over the Top Best Effort VoIP Packet Sizes (with overheads) for Varying
Levels of Segmentation
VoIP Codec G.729 G.729 G.711 G.711
IP Version IPv4 IPv6 IPv4 IPv61 Way Segmentation 536 bit 696 bit 1664 bit 1824 bit
2 Way Segmentation 292 bit 372 bit 856 bit 936 bit
4 Way Segmentation 170 bit 210 bit 452 bit 492 bit
8 Way Segmentation 109 bit 129 bit 250 bit 270 bit
Note: The packet sizes summarized in Table 11 assume that Robust Header Compression
(RoHC) is not utilized for these over the top VoIP services.
For example, with 8 way segmentation, a G.729 codec and IPv4, a TBS = 109bits is
required. This means that the UE must have 8 separate transmissions scheduled each of
109bits in size, during each 20mecs VoIP frame period. Without segmentation, the UE onlyrequires a single transmission of 536 bits scheduled during each 20mecs VoIP frame period.
Clearly less segmentation is less demanding on air interface resources. However, this comes
at the expense of degraded receiver sensitivity, as is summarized in Table 12.
Table 12: Over the Top Best Effort VoIP Receiver Sensitivity for Varying Levels of
Segmentation (for EVehA3 km/h, 2dB NF and 10% iBLER)
VoIP Codec G.729 G.729 G.711 G.711
IP Version IPv4 IPv6 IPv4 IPv6
1 Way Segmentation -108.7 dBm -108.1 dBm -104.6 dBm -104.3 dBm
2 Way Segmentation -110.8 dBm -109.6 dBm -107.4 dBm -107.2 dBm
4 Way Segmentation -113.5 dBm -111.7 dBm -109.5 dBm -108.9 dBm
8 Way Segmentation -114.5 dBm -114.3 dBm -111.4 dBm -111.2 dBm
For the above mentioned example (G.729 & IPv4), the receive sensitivity ranges from -
108.7dBm without segmentation to -114.5dBm with 8 way segmentation. Furthermore,
comparing the receiver sensitivities in Table 10 and Table 12, the link budget benefits
attributable to TTI bundling combined with more HARQ transmissions are immediately
apparent, -122.9dBm for TTI bundled AMR 12.2 VoIP versus -114.5dBm for G.729, IPv4 and 8
way segmentation.
2.1.6 Uplink Explicit Diversity Gains
The SINR performance figures considered by Alcatel-Lucent in uplink and downlink link
budgets are based on link level simulations that already account for the corresponding
transmit and receive diversity gains. For the uplink the default assumption is 1x2 receive
diversity (2RxDiv), the gain associated with 2RxDiv is accounted for directly in the SINR
figures.
Table 13 summarizes the receive diversity gains observed from link level simulations
performed for a range of different eNode-B receive antenna correlation assumptions.
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Table 13: Receive Diversity Gains From Link Level Simulations
Correlation Low Medium High
4RxDiv Gain(QPSK) 4.2 dB 4.1 dB 3 dB
8RxDiv Gain(QPSK) 7.5 dB 6.2 dB 5 dB
Power Combining Gain 3dB (4RxDiv) and 6dB (8RxDIv)
Spatial Diversity Gain Large Medium Small
Relative to 2RxDiv performances
MRC loss in highly correlated channels
It can be seen from Table 13 that 4RxDiv gains range from 3 to 4.2dB and 8RxDiv gains from
5 to 7.5dB. For high correlation conditions the 8RxDiv gains are less than that attributable
to the power combining gain due to an MRC loss.
Table 14 details the impact on the SINR figures considered by Alcatel-Lucent for link budgetpurposes for four different UL receive diversity schemes (these are aligned with the High
correlation scenario from Table 13 with some additional margin):
Table 14: SINR and IoT Impact due to UL Receive Diversity Scheme
UL Rx Diversity
SchemeSINR Impact IoT Impact
1 RxDiv -2.5 dB +1 dB
2 RxDiv 0 dB 0 dB
4 RxDiv +2.5 dB -1 dB
8 RxDiv +4.5 dB -2 dB
For example, to account for 1x4 receive diversity (4RxDiv) on the uplink an additional 2.5dB
gain is considered on the (2RxDiv) SINR figures from link level simulations.
Also detailed in Table 14 is the assumed impact on the default average IoT (discussed more
in section 2.1.7). The underlying assumption here is that the reduced SINR requirements
associated with higher order receive diversity schemes leads to a reduced SINR for cell
edge UEs which in turn corresponds to a reduction in the average IoT imposed on adjacent
cells.
Internal: Currently we do not have simulations to strongly back these IoT reduction
assumptions other than that which can be found at the following:https://sps.sg.alcatel-
lucent.com/sites/Global Sales Organization/wreless_toolsanexptse/LTE Simulations WG/Shared Documents/03 -
System Level Simulations/2010_09 - UL - TDD - 8RxDiv vs 2RxDiv IoT Impact
2.1.7 Interference Margin
Generally, sensitivity figures are derived considering only thermal noise. However, in a link
budget analysis, the real interference, Ij(UL), should be considered and not only the thermal
noise. This means that the received power, Cj(UL), should satisfy the following condition:
dBdBm ceInterferendBmj(UL)MarginySensitivitC +
where
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+=
WN
WNI10logMargin
th
thj(UL)
ceInterferen dB
The MarginInterference is the interference rise over that of thermal noise due to inter-cell
interference. Nthis the thermal noise (-174 dBm/Hz) and W is the used PRB bandwidth (Hz).
Note that the assessment of the interference margin is totally different from the classical
relationship between uplink cell load and noise rise considered in CDMA and WCDMA
systems. Ij(UL)is the interference due to adjacent cells utilizing the same PRB at the same
time. Note that this interference could also be considered to comprise of external
interference from other systems such as MediaFLO or DTC Channel 51.
LTE resources are divided into resource blocks (set of OFDM symbols and frequencies). The
interference per resource block will depend on the probability that resource blocks of same
frequency are simultaneously used in the surrounding cells. However, LTE system is likely to
be deployed with a frequency reuse of 1. The interference on a given resource block can
therefore be high.
Assessing the interference level enables the derivation of the interference margin to be
accounted for in link budgets used for coverage (cell range) evaluation. In CDMA or WCDMA
systems, the interference margin was derived from power control equations, these
equations established a linkage between the number of users transmitting in the cell (or
the cell load) to the interference margin (or noise rise). In LTE some specific power control
schemes are defined with some flexibility in the definition of the parameters offering
various power control strategies to be adopted and consequently impacting the
interference margin, IoT, to be considered in link budget analyses.
For overlay and Greenfield deployment scenarios different approaches can be adopted for
selecting the system IoT target and tolerable adjacent cell RB loadings.
For a pure 100% overlay, the inter-site distance of the incumbent system must berespected. The link budget enables the determination of the ideal IoT target sothat the system can reach a given data rate at cell edge,
o From this IoT target the tolerable RB loading of adjacent cells can beestimated.
For a Greenfield network, there is more flexibility to set the IoT target versus thedata rate expectations at cell edge.
o This can be performed for a target RB loading for adjacent cells.A typical IoT target considered in LTE link budgets is 3dB. Such an IoT target will have a
corresponding loading for adjacent cells for the cell range computed using the link budget
formulation presented in this document.
The average IoT is dependent upon the cell edge data rate (SINR) that is targeted by UEs in
adjacent cells. Higher cell edge SINR targeted by UEs in adjacent cellsHigher average IoT Larger cell sizes Lower cell edge rates can be achieved by UEs in adjacent cells
Lower average IoT (e.g. NGMN Case 3)
Smaller cell sizes Higher cell edge rates can be achieved by UEs in adjacent cellsHigher average IoT (e.g. NGMN Case 1)
An example from some system level simulations performed under NGMN Case 3 conditions
(a coverage/link budget limited scenario) is presented in Figure 10 (assuming 100% resource
block loading, 10 UEs per sector, full buffer simulations, 10MHz bandwidth).
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0 kbps
1000 kbps
2000 kbps
3000 kbps
4000 kbps
5000 kbps
6000 kbps
7000 kbps
1.0 dB 1.5 dB 2.0 dB 2.5 dB 3.0 dB 3.5 dBIoT
CellThroughput
Figure 10: NGMN Case 3 Coverage limited scenario, 100% resource block loading,
10 UEs per sector, full buffer simulations
Figure 10 illustrates the impact of allowing a different average IoT on the spectral
efficiency of the uplink. It can be seen that for this particular scenario the optimal IoT is
between 2.5 and 3dB. Such scenarios are more typical of deployments that are more
coverage rather than interference limited which is typical of the cases commonly
considered in link budget analyses.
A further example performed under NGMN Case 1 conditions (an interference/capacity
limited scenario) is presented in Figure 11 (assuming 100% resource block loading, 10 UEsper sector, full buffer simulations, 10MHz bandwidth).
0 kbps
1000 kbps
2000 kbps
3000 kbps
4000 kbps
5000 kbps
6000 kbps
7000 kbps
8000 kbps
9000 kbps
10000 kbps
0 dB 5 dB 10 dB 15 dB 20 dB
IoT
CellThr
oughput
Figure 11: NGMN Case 1 Interference/capacity limited scenario, 100% resource block
loading, 10 UEs per sector, full buffer simulations
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Figure 11 illustrates the impact of allowing a different average IoT on the spectral
efficiency of the uplink. It can be seen that for this particular scenario the optimal IoT is
greater than 5dB. However, in this case the link budget is not constraining and thus from a
link budget perspective there is no issue with tolerating a higher IoT.
Note that while the simulations indicate there are gains to be had at IoTs of up to 15dB ormore, operating points greater ~5.5dB are not currently recommended by Alcatel-Lucent.
As was mentioned in section 2.1.6, when considering different receive diversity schemes,
the default IoT recommendations are offset according to the figures recommended in Table
14.
2.1.8 Shadowing Margin
From the previous section, the link budget should satisfy the following equation:
dBdBm ceInterferendBmj(UL)MarginySensitivitC +
This equation should be satisfied from a statistical point of view with a given probability,
Pcov, (coverage probability) within the cell. Typically, the received power should be better
than the sensitivity over more than 95% of the cell area:
covceInterferendBmj(UL) PMarginySensitivitCProba dBdBm +
Generally, a target of 95% cell coverage is considered in dense urban, urban and suburban
environments, while 90% is considered in rural environments, but this is dictated by the
operators coverage quality objectives.
The received power from a mobile within the cell will depend upon the shadowing
conditions due to obstacles between the UE and the base station antennas. These slow
shadowing variations (in dB) can be represented as a Gaussian random variable with a zero-
mean and a standard deviation that is dependent upon the environment (typically between5 to 10 dB).
Due to the Gaussian properties of the shadowing, a margin called the shadowing margin
can be computed and incorporated in the link budget calculations to consider the coverage
probability requirement, either probability at cell edge or over the cell. The following
formulas are used to derive the shadowing margins according to the specified coverage
probability:
=
2
Marginerfc
2
11P dB
Shadowing
bordercellcov
( )
+++=
+
bab1erf1eaerf1
21P 2b
2ab1
areacellcov
Where
2
Margina
Shadowing=
( ) 210ln
Kb 2=
K2is the propagation model coefficient.More details on the way these equations are derived can be found in [1].
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In order to guarantee a given level of indoor coverage, a penetration margin is considered
in the link budget (see sections 2.1 and 2.1.11). Either this penetration margin is defined as
a worst-case (e.g. 95thpercentile value) value for which indoor coverage must be ensured
or as an average penetration loss value with an associated standard deviation. In the
former case, both variations of penetration and shadowing can be considered together
through a single Gaussian random variable with the following composite standard deviation:
2npenetratio
2shadowing +=
In order to simplify the link budget it is recommended to consider the former approach, i.e.
the penetration margin defined in Section 2.1.11 is therefore considered as a worst case
value, without the requirement to consider any additional standard deviation.
Table 15 summarizes some typical shadowing margins for a typical path loss slope, K2 =35:
Table 15: Example of Shadowing Margins
Shadowing StandardDeviation
Cell AreaCoverage
Probability
Cell EdgeCoverage
Probability
ShadowingMargin
95% 87.7% 11.7 dB10 dB
90% 77.7% 7.7 dB
95% 86.2% 8.7 dB8 dB
90% 75.1% 5.4 dB
95% 84.9% 7.2 dB7 dB
90% 73.3% 4.3 dB
95% 83.9% 5.9 dB6 dB
90% 70.9% 3.3 dB
2.1.9 Handoff Gain / Best Server Selection Gain
Unlike UMTS/WCDMA or CDMA, there is no soft-handoff functionality for LTE. Therefore, no
soft-handoff gain should be considered for LTE.
However it would be too pessimistic to only consider the shadowing margin computed with
one cell as in section 2.1.8: a mobile at the cell edge can still handover to or originate a
call on a neighboring cell with more favorable shadowing, i.e. a lower path loss.
Some models have been derived to compute such a hard handoff gain, taking into accounthandoff hysteresis thresholds and connection delays [2] [3]. Such a model collapses to that
of soft-handoff computations when the handoff threshold and the connection delays are
equal to zero. It is also important to note that while this is referred to in the link budget as
a handoff gain it could equally well be referenced as a best server selection gain.
Note that this hard handoff gain can be considered for any system without soft handoff. So
this is the case for GSM. Note that the handoff gain for LTE should be somewhere in
between that which may be considered for GSM and that for a soft handoff scenario for
WCDMA or CDMA.
A shadowing margin, which is partially mitigated by the handoff gain, is only considered in
the link budget due to uncertainties in the estimation of the path loss and cell range. As
the uncertainty in the prediction of the path loss is reduced (a reduction in the standarddeviation of shadowing) the shadowing margin and handoff gain will also be reduced. If
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there are no uncertainties in the estimation of the path loss and the corresponding cell
range, there will be no need to consider any shadowing margin or handoff gain.
Internal: However we are not used to considering such a gain in GSM. It is highly
recommended to consider such a hard handoff gain, above all to have favorable link budget
comparison with CDMA or WCDMA, both of which consider a soft handoff gain in their linkbudgets.
Table 17 provides some examples of the shadowing margin and handoff gain for different
coverage probability targets and shadowing standard deviations. This example is based on
the assumptions listed in Table 16:
Table 16: Assumptions for Hard Handoff Gain Computations
Antenna Height 30 m
K2 Propagation Model 35.2
Shadowing Correlation 0.5
Hysteresis 3 dB
HO sampling time 20 msec
# of samples to decide HO 4 samples
Correlation distance 50 m
Note that the assumptions in Table 16 for the Hysteresis and HO sampling time are
relatively conservative so as to ensure that the handoff gains considered in the LKB are
evaluated with a reasonable degree of confidence.
Table 17: Example of Hard Handoff Gain
Handoff GainShadowing
Standard
Deviation
Cell Area
Coverage
Probability
Cell Edge
Coverage
Probability
Shadowing
Margin
Soft
Handoff
Gain3
km/h
50
km/h
100
km/h
6 dB 90% 71% 3.3 dB 2.7 dB 2.3 dB 2.1 dB 2.0 dB
6 dB 95% 84% 5.9 dB 2.8 dB 2.5 dB 2.2 dB 2.0 dB
7 dB 90% 73% 4.3 dB 3.1 dB 2.8 dB 2.6 dB 2.4 dB
7 dB 95% 85% 7.2 dB 3.4 dB 3.1 dB 2.8 dB 2.6 dB
8 dB 90% 75% 5.4 dB 3.6 dB 3.4 dB 3.1 dB 2.8 dB
8 dB 95% 86% 8.7 dB 3.9 dB 3.6 dB 3.3 dB 3.0 dB10 dB 90% 78% 7.7 dB 4.7 dB 4.4 dB 4.1 dB 3.7 dB
10 dB 95% 88% 11.7 dB 5.0 dB 4.8 dB 4.4 dB 4.0 dB
Based on these results, a 3.6dB handoff gain can be assumed for typical DU, U and SU
deployment conditions (95% area reliability, 8dB shadowing standard deviation and 3km/h)
and 2.6dB in typical Rural conditions (90% area reliability, 7dB shadowing standard
deviation and 50km/h).
Note that the full handoff gain is only applicable for UEs located at the cell edge. In the
uplink link budget we consider one service (data rate) that is guaranteed at the cell edge,
the more demanding services are supported in a subset of the coverage area. Consequently,
the other services will not take benefit of the full handoff gain. Figure 12 illustrates the
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handoff gains computed for UE locations between the eNode-B and the cell edge. Note that
this is an example for the same assumption as shown in Table 16 for a shadowing standard
deviation of 8dB and 95% coverage reliability.
0.0 dB
0.5 dB
1.0 dB
1.5 dB
2.0 dB
2.5 dB
3.0 dB
3.5 dB
4.0 dB
0% 20% 40% 60% 80% 100%
% of Cell Range
HandoffGain
Figure 12: Handoff Gains for UE Locations between the eNode-B and the Cell Edge
2.1.10 Frequency Selective Scheduling (FSS) Gain
There are a number of ways the LTE system can manage the potentially considerably
frequency selective channel:
Schedule the best groups of RBs (Resource Blocks) to individual UEs according tothe channel conditions for specific UEs (frequency selective scheduling)
Make no specific consideration to the frequency selectivityo Frequency non-selective schedulingo A variant upon this is to randomly hop frequencies (RBs) for retransmissions
and/or successive TTIs
For frequency selective scheduling, consider as an example, an uplink where an eNode-B is
serving 3 contending UEs. For each UE, the eNode-B has knowledge of the quality of the
radio channel (by means of the uplink SRS) and as such can form quality metrics for each
individual RB for each UE on the UL. Based on these quality metrics the scheduler can
formulate which resource block or group of resource blocks is most advantageous to
allocate to each of the contending UEs on the uplink. This process is highlighted on Figure13.
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12
34
56
78
9
UE 1
UE 2
UE 30
1
2
3
4
5
6
7
8
Priority
Metric
PRB Index
UE 1
UE 2
UE 3
0
2
4
6
8
10
12
1 2 3 4 5 6 7 8 9
PRB Index
PriorityMetric
Figure 13: Per UE quality metrics for each RB and the consolidated priority metric
for each RB
By allocation of the RB groupings according to the right hand diagram in Figure 13 it is
possible to ensure that each UE is more likely to get allocated individual resource blocks
that have more favorable channel conditions, thus resulting in enhanced link budget
performances. This can be thought of a type of interference co-ordination scheme,
whereby it is possible for the system to avoid interference by appropriate resource block
allocation. A similar principle also applies on the downlink.
One alternative to such a frequency selective scheduling approach is to consider only an
average of the channel qualities across the entire band for each UE, see Figure 14.
12
34
56
78
9
UE 1
UE 2
UE 30
1
2
3
4
5
6
Priority
Metric
Resource Unit Index
UE 1
UE 2
UE 3
Figure 14: Frequency Non-Selective Scheduling
With such an approach the scheduler losses the ability to differentiate the best RB or group
of RBs depending on the channel quality of individual resource blocks. Thus as aconsequence the system can not take benefit of the corresponding link budget benefits.
The gains attributable to frequency selective scheduling are dependent upon the channel
model and the HARQ operating point. The gains can be estimated by means of system level
simulations performed both with and without consideration of frequency selective
scheduling. The difference in cell edge performances dictates the link budget gain that can
be attributed to frequency selective scheduling.
Table 18 summarizes the frequency selective scheduling gains, derived from simulations,
for two HARQ operating points and three different channel models.
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Table 18: Frequency Selective Scheduling Gains
Channel Model1% pBLER
(high initial BLER)
10% iBLER
(low initial BLER)
VehA3 0.5 dB 1.8 dBVehA50 0.0 dB 0.0 dB
VehA120 0.0 dB 0.0 dB
Consider as an example from Table 18:
10% iBLER HARQ operating point, VehA3 channel conditions FSS Gain = 1.8dB This means the throughput with FSS is 50% greater than the case without FSS
Note: the FSS gain is only applied for services in the UL link budget where the RBs for the
service can be allocated from all the available RBs. For example the PUCCH and Attach link
budgets do not benefit from this gain as the RB allocation is restricted.
2.1.11 Penetration Losses
The penetration losses characterize the level of indoor coverage targeted by the operator
(deep indoor, indoor daylight, window, in-car, outdoor, etc). They are highly dependent on
the wall materials and number of walls/windows to be penetrated.
As mentioned earlier, Section 2.1.8, the penetration losses can be specified either as an
average penetration loss with an associated standard deviation or as a single worst case
penetration margin (the later case is recommended). Table 19 summarizes some typical
worst case penetration losses for the most common frequency bands.
Table 19: Typical Penetration Losses for Common Frequency Bands
Penetration MarginFrequency
band Dense
UrbanUrban
Suburban
Indoor
Suburban
Incar
Rural
Incar
700 MHz 17 dB 14 dB 11 dB 5 dB 5 dB
800 MHz 17 dB 14 dB 11 dB 5 dB 5 dB
850 MHz 18 dB 15 dB 12 dB 6 dB 6 dB
900 MHz 18 dB 15 dB 12 dB 6 dB 6 dB
1800 MHz 20 dB 17 dB 14 dB 8 dB 8 dB
1900 MHz 20 dB 17 dB 14 dB 8 dB 8 dB
AWS 20 dB 17 dB 14 dB 8 dB 8 dB
2100 MHz 20 dB 17 dB 14 dB 8 dB 8 dB
2600 MHz 21 dB 18 dB 15 dB 9 dB 9 dB
2.2 Final MAPL and Cell Range
The final uplink link budget equations become:
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( )dBdBdB
dBdBdBdBdBm
RxRxnPenetratio
BodynPropagatioTxTxHMaxTX_PUSCdBmj(UL)
LossGaininargM
ssLoLossesLossGainPC
+
+=
And
dBdBdBdBdBm FSSHOShadowingIoTdBmj(UL) GainGainMarginMarginySensitivitC ++
For each service to be offered by the operator, this relationship allows computation of the
maximum propagation losses that can be afforded by a mobile located at the cell edge,
that is to say the Maximum Allowable Path Loss (MAPL):
dBdBdB
dBdB
dBdBdBdBdBdBm
FSSHOShadowing
IoTdBmnPenetratio
BodyRxRxTxTxHMaxTX_PUSCdBj(UL)
GainGainMargin
MarginySensitivitinargM
LossossLGainossLGainPMAPL
++
++=
ReferenceSensitivity
Transmit Power
Lossesand Margins
Gains
= MAPL
Interferencecell radius
Maximum AllowablePathloss
Reference Sensitivity
Max UE transmit Power
Gains - Losses- Margins
Interference marginextra cell interference
Figure 15: Uplink Link Budget Elements
Considering the most demanding service for which contiguous coverage is to be offered, the
following can be used to determine the maximum allowable cell range for deployment of
the system:
)Service(UL102(UL)1(UL)dBj(UL)(UL)dBRLogKKMAPLMinMAPL +==
2.2.1 Propagation Model
K1 and K2 characterize the propagation model. For Macro-cell coverage, the following
propagation models are used:
( ) ( )km1021kmopagationPr RLogKKRossesL += For 700, 850 or 900 MHz, the Okumura-Hatamodel is used:
o ( ) ( ) ( ) cmb10Mhz101 KHaHLog82.13FLog16.2655.69K ++= For AWS, 1.9GHz or 2.1GHz band, the COST-231 Hatamodel is used:
o ( ) ( ) ( ) cmb10Mhz101 KHaHLog82.13FLog9.333.46K ++= For 2.6GHz, a Modified COST-231 Hatamodel is used:
o The COST-231 Hata is limited to frequency between 1.5GHz and 2GHz.Based on measurements at higher frequency (3.5GHz, 2.5GHz), Alcatel-
Lucent proposed the following modified formula:
o( ) ( ) ( ) cmb10
MHz
10101 KHaHLog82.132000
F
Log202000Log9.333.46K +
++=
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o The Modified Cost-231 Hata model is only considered applicable forSuburban and Rural morphologies. For Dense Urban and Urban morphologies
the Cost-231 Hata model is considered to be a better representation.
Whereo ( )b102 HLog55.69.44K = o ( ) [ ] 597.4)xH(11.75(Log3.2 2m10 >= cm KforHa o ( ) ( )[ ] [ ] 50.8-)(FLog1.567.01.1 MHz1010 = cmMHzm KforHFLogHa
FMHzrepresents the operating frequency in MHz. Hbis the height of the eNode-B antenna in
meters and Hmis the height of the UE antenna in meters (typically 1.5m).
A morphology correction factor, Kc, is used depending on the type of environment, e.g.
dense urban, urban, suburban, rural (typical values from calibration measurement
campaign).
Internal: For the propagation model, it is always better to use a calibrated propagation
model for the country or city you are studying if a calibration measurement campaign isavailable. Otherwise, use the default morpho correction factors defined in the document
Clutter Classes For Radio Network Planning.
2.2.2 Site Area
Tri-sector sites are commonly used to offer 3G coverage and this is also the case for LTE.
Figure 16: Intersite Distance and Site Area
The relationship between the cell range and the site area (3 sector sites) is defined by the
following:
2
)Service(UL
2
)Service(UL R1.95R8
39SiteArea ==
The number of sites to cover a given area (due to coverage limitation) can then be derived.
Note: In the case of tri-sector configurations it is assumed that the antenna is tilted such
that the antenna boresight is directed at the cell edge.
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2.3 Impact of RRH and TMA
2.3.1 RRH
Remote Radio Heads (RRH) are a popular solution that enables to separate the RF part of
the eNode-B and locate it physically close to the antenna, resulting lower feeder losses
between the eNode-B and the antenna (lower losses on UL, more effective radiated power
on the DL). Depending on where the RRH is located relative to the antenna, more or less
losses have to be considered in the uplink link budget:
At least 0.5dB losses should be considered due to the jumper required between theRRH and the antenna, applicable where the RRH is deployed very close to the
antenna,
Higher losses should be considered if the RRH is installed farther from the antenna(e.g. RRH at rooftop but still some non-zero length of feeder between the RRH and
the antenna).
The other parameters of the link budget are not modified.
2.3.2 TMA
Tower Mounted Amplifiers (TMA) (also called Mast Head Amplifiers (MHA) or Tower Top Low
Noise Amplifiers (TTLNA)) can be used to enhance the uplink coverage of eNode-Bs with
high feeder losses between the eNode-B and the antenna, allowing the required number of
sites to be minimized (in the case of coverage-limited scenarios but not for capacity-
limited scenarios) or allowing the reuse of incumbent 2G/3G sites to be maximized while
offering higher data rates than in 2G/3G.
For example, TMAs can be particularly beneficial if LTE is deployed in the 2.6GHz band,while incumbent 2G/3G sites were deployed in a lower band (e.g. 2GHz or even 850 or
900MHz), this allows the uplink LTE cell range, affected by higher propagation losses at the
higher frequency, to be enhanced.
As for any active element inserted in the reception chain of an eNode-B, the impact of a
TMA on the link budget can be assessed by means of the Friis formula.
feederTMA
BeNode
TMA
feederTMAoverall
gg
1n
g
1nnn
+
+=
with 10NF
element
element
10n = and 10G
element
element
10g = ,
where NFfeeder= -Gfeeder= Feeder Losses. The typical TMA characteristics are NFTMA= 2dB,
GTMA= 12dB and Insertion Losses = 0.4dB
This has 2 key impacts on the link budget parameters:
Compensation of the feeder losses, Reduction in the overall Noise Figure of the eNode-B.
However, TMA insertion losses of 0.4dB must be considered in the DL link budget.
The typical gain on the MAPL for a 3dB feeder loss is approximately 2.7dB, which
corresponds to 36% less sites, thanks to TMA usage. Note that such gains are only applicable
for scenarios where uplink coverage remains as the limitation (i.e. low traffic scenarios).
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2.4 Uplink Budget Example
Table 20 presents some example of the entire uplink budget analysis for a dense urban
environment with deep indoor penetration for a range of different services.
The key objective of the air interface coverage analysis is to formulate a link budgetfrom which the per-service MAPLs and the corresponding cell ranges can be computed
(see the rows in red in Table 20).
Table 20: Typical PUSCH link budgets for a tower mounted RRH deployment in Dense
Urban VehA3 channel conditions at 700MHz (128kbps guaranteed at cell edge)
The cell ranges computed above are for a Hata propagation model for a 25m eNode-B
antenna height, a 1.5m UE antenna height a clutter correction factor of 0dB. WherePL=K1+K2xlog10(dkm), K1=124.8 and K2=35.7.
Internal: The default ALU link budget can be found on the intranet: Alcatel-Lucent LTE-
FDD Link Budget.
Based on the services to be guaranteed at cell edge the limiting Maximum Acceptable Path
Loss (MAPL) can be derived.
2.5 Uplink Common Control Channel Considerations
There are two main common and control channel considerations that should be assessed for
an LTE network design to ensure that they will not limit the coverage. These include:
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Attach Procedure (limiting message RRC Connection Request) ACK/NACK Feedback
o Either punctured onto the Physical Uplink Shared Channel (PUSCH)o Or over the Physical Uplink Control Channel (PUCCH)
Periodic CQI Reportso Over the Physical Uplink Control Channel (PUCCH)
2.5.1 Attach Procedure
Figure 17 illustrates the procedure that the UE must go through to Attach to an LTE
network. From a link budget perspective the limiting message from messages 1, 2, 3, 4, 5,
15 and 16 (that involve the air interface) must be considered to assess any link budget
constraints.
eNBUE MME
RACH Preamble (1)
Grant and TA (2)
RRC Connection Request (3)
RRC Connection Setup (4)
RRC Connection Setup Complete (5)
SGW PGW
Attach request (6)
Authentication (optional)/ security (7-8)Create Default Bearer
Request (9) CDB Request(10)
Attach accepted(13)
Create Default Bearer Response(12)
CDB Response(11)
RRC Connection reconfiguration(14)
RRC Connection reconfiguration complete(15)
Attach complete(16)
No MME Relocation
1st UL bearer packet
Update Bearer Request (20)
Update Bearer Response (21)
1st DL bearer packet
eNBUE MME
RACH Preamble (1)
Grant and TA (2)
RRC Connection Request (3)
RRC Connection Setup (4)
RRC Connection Setup Complete (5)
SGW PGW
Attach request (6)
Authentication (optional)/ security (7-8)Create Default Bearer
Request (9) CDB Request(10)
Attach accepted(13)
Create Default Bearer Response(12)
CDB Response(11)
RRC Connection reconfiguration(14)
RRC Connection reconfiguration complete(15)
Attach complete(16)
No MME Relocation
1st UL bearer packet
Update Bearer Request (20)
Update Bearer Response (21)
1st DL bearer packet
Figure 17: LTE Attach Procedure
The limiting message of the attach procedure over the air interface is message 3 (RRC
Connection Request). This message utilizes 2 resource blocks with MCS 3, delivering an
average effective data rate of 41.6 kbps after an average of 2.5 HARQ transmissions
(maximum of 5). The SINR requirements for this message is -4.4 dB (including margins),
based on link level simulation studies.
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Figure 18 summarizes an uplink budget formulated for a dense urban morphology in the
700MHz band. This link budget compares the Attach link budget with VoIP, 32, 64 and
128kbps services.
Figure 18: LTE Link Budget for Message 3 of the LTE Attach Procedure (compared with
VoIP, 32, 64, 128kbps services)
Note: For that the RRC Connection Request message can not be assigned to any available
resource blocks on the uplink. As a consequence no frequency selective scheduling gain isconsidered for this link budget.
It can be seen from Figure 18 that the Attach link budget is not limiting since equivalent to
a 32kbps cell edge service.
2.5.2 ACK/NACK Feedback
When users are receiving packets on the DL over the Physical Downlink Shared Channel
(PDSCH) they must send steady streams of ACK/NACK transmissions over the UL to either
acknowledge or not acknowledge the reception of the downlink packets. Correct reception
of such ACK/NACK transmissions is critical for optimizing the efficiency of the DL
transmissions.
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The first Alcatel-Lucent implementation for such transmissions is to puncture the ACK/NACK
transmissions onto the Physical Uplink Shared Channel (PUSCH). In the longer term it is
expected to carry such transmissions over the Physical Uplink Control Channel (PUCCH).
For either solution the ACK/NACK transmission utilizes 1 resource block with QPSK. The
SINR requirements for this message are -1.7dB and -5.8dB for puncturing on the PUSCH andPUCCH, respectively (including margins), based on link level simulation studies.
Figure 19 summarizes an UL link budget formulated for a dense urban morphology in the
700MHz band. This link budget compares the ACK/NACK link budgets for puncturing over
the PUSCH and PUCCH options with VoIP, 32, 64, and 128kbps services.
Figure 19: LTE Link Budget ACK punctured onto PUSCH and over PUCCH (compared withVoIP, 32, 64 and 128kbps services)
Note: As the PUCCH only uses a subset of the uplink resource blocks no frequency selective
scheduling gain is considered for the ACK/NACK over PUCCH link budget. However, this is
not the case for ACK/NACK over PUSCH.
From Figure 19 it can be seen that for either option (PUSCH or PUCCH) the ACK/NACK link
budget does not limit the LTE coverage but rather coverage will be first limited by the UL
service link budgets, e.g. VoIP AMR 12.2 or 32kbps.
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2.5.3 Periodic CQI Reports
The periodicity and frequency resolution to be used by a UE to report CQI are both
controlled by the eNode-B. In the time domain, both periodic and aperiodic CQI reporting
are supported. The Physical Uplink Control Channel (PUCCH) is used for periodic CQI
reporting only; the Physical Uplink Shared Channel (PUSCH) is used for aperiodic reporting
of the CQI, whereby the eNode-B specifically instructs the UE to send an individual CQI
report embedded into a resource which is scheduled for uplink data transmission.
Internal: Alcatel-Lucent does not yet support CQI reporting over PUCCH (as at LA2.0) but
this is planned for LA3.0
Focusing on the periodic CQI reports over the PUCCH, the most limiting 8bit CQI report
utilizes 1 resource block with QPSK. The SINR require