performance of relays in lte-advanced networks apply standardized lte rel.8 power control on ue-enb...
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![Page 1: Performance of Relays in LTE-Advanced Networks Apply standardized LTE Rel.8 power control on UE-eNB and UE-RN links. – Optimize power control parameters at eNBs and RNs. • Investigate](https://reader036.vdocuments.net/reader036/viewer/2022062602/5e9e319d3508db64c4111292/html5/thumbnails/1.jpg)
1 © Nokia Siemens Networks
Ömer Bulakci, Abdallah Bou Saleh
PhD candidates of Helsinki University of Technology (TKK)@ Nokia Siemens Networks
Performance of Relays in LTE-Advanced Networks
18.02.2010
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Content
• Introduction
• Goal
• System Parameters
• Uplink performance evaluation–Power control
• Downlink performance evaluation–RN coverage area extension
• Conclusions
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Introduction (1/2)
Requirements for LTE-Advanced:– 1 Gbps on the downlink and 500 Mbps on the uplink.– Higher peak and average spectral efficiency.– More homogenous distribution of the user experience over the
coverage area.
Challenges:– Severe propagation losses at the cell edge, resulting in significant
capacity and coverage problems.– Straight-forward Solution: Smaller sectors or equivalently more
eNBs.▪ Cost inefficient
Can we do better?
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• Promising Solution: Heterogeneous deployments – Decode and Forward Relay Nodes
– Low total cost of operation.– More homogeneous user experience.– Cell coverage area extension.
Introduction (2/2)
(relay-UEs)
(macro-UEs)
Yes, WE CAN!
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Goal
• Investigate the performance of LTE-Advanced uplink in relay deployment
– Apply standardized LTE Rel.8 power control on UE-eNB and UE-RN links.
– Optimize power control parameters at eNBs and RNs.
• Investigate the performance of LTE-Advanced downlink in relay deployment
– Study the impact of RN coverage extension via biasing in cell selection on the system performance.
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6 © Nokia Siemens Networks
System Layout 19 tri-sectored sites
Bandwidth 10 MHzTraffic Model Full Buffer
Noise PSD -174 dBm/Hz
Shadowing σmacro = 8dBσrn cell = 10dB
Penetration Loss 20 dB
Highest MCS (AMC) 64-QAM – R: 9/10
Resource partitioning Reuse 1Scheduler Round Robin
Antenna height 25 m (above rooftop)
Antenna configuration 2 Tx, 2 Rx
Transmit Power 46 dBm
Antenna gain 14 dBi
Noise Figure 5 dB
eNB Antenna Pattern(Horizontal)
-min[12 (θ/ θ3dB)2, Am]θ3dB = 70o & Am = 25 dB
Antenna height 5 m (below rooftop)
Antenna configuration
2 Tx, 2 RxOmni-directional
Transmit Power 30 dBm
RN-UE antenna gain 5 dBi
RN-eNB antenna gain 7dBi
Noise Figure 7 dB
Backhaul Link Ideal
Syst
em P
aram
eter
s
eNB
Spe
cific
RN
Spe
cific
System ParametersAntenna configuration 1 Tx, 2 Rx
Noise Figure 9 dB
UE drop Uniform - 10 UEs per sector – IndoorU
E Sp
ecifi
c
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Uplink Performance Evaluation
~ Power Control ~
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Basics
• The Open Loop Power Control formula is investigated.
I. LTE Rel.8 fractional power control (1/2)
}log10,min{ 100max LMPPP ⋅+⋅+= α Pmax : Max allowed UE transmit power [23 dBm] P0 : Parameter to control SNR target [dBm] M : # of PRBs allocated to one UE : Cell specific path loss compensation factor L : Downlink path loss estimated at UE [dB]
• P0 can be selected from the set of [-116:1 dB:Pmax] in dBm.• We investigated P0 in the range of [-113:2 dB:-7] in dBm.
α
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BasicsI. LTE Rel.8 fractional power control (2/2)
• [0.0, 0.4, 0.5, 0.6, 0.7, 0.8, 0.9, 1.0] = 1.0 Full Compensation Power Control (FCPC) [0.4, 0.6, 0.8] Fractional Power Control (FPC)
∈αα ⇒∈α ⇒
FCPC compensates the path loss fully and hence increases the performance of cell edge users.
FPC utilizes a partial compensation factor for the path loss and improves the performance of cell center users by inducing an acceptable inter-cell
interference.
No Power Control (No PC): Fixed Tx Power
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BasicsII. Methodology • Power control parameter optimization in relay deployment is done in four steps.
Optimization ineNB-only deployment
Step 1:
Step 3:
Optimization atRNs
Step 4:
Optimization ateNB
Apply toRelay
deployment
Step 2:
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Optimization ineNB-only deployment
Step 1:
InfoPoint
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Performance Metrics
• Cell Coverage: 5th %-ile user throughput multiplied by the number of users per sector.
Drop # :
• Cell Capacity: Aggregate user throughput (TP) per TTI averaged over user drops.
1
TTI
2
PRB
D
Cell Capacity = mean(TP1,TP2,…,TPD)
TP1 TP2 TPD
+
TP5%-ile
Cell Coverage =
TP5%-ile * numUE
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0 500 1000 1500 2000 2500 3000 3500 40005000
6000
7000
8000
9000
10000
11000
12000
13000
14000
Cel
l Cap
acity
[kbp
s]
Cell Coverage [kbps]
Cell Capacity vs Cell Coverage
αeNB = 1
αeNB = 0.8
αeNB = 0.6
αeNB = 0.4
Cell Capacity vs. Cell CoverageParameter Optimization in eNB-only Deployment
Cell CapacityOriented
• Hull Curve: At the final point, the percentage-wise increase in cell capacity is higher than percentage-wise decrease in cell coverage.
Hull Curve
Cell CoverageOriented
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Performance Metrics • Receiver Dynamic Range: The difference between the 5th%-ile and 95th%-ile of the CDF of the total received power per PRB (Wanted Signal Power + Interference Power).
Receiver DynamicRange
Example Scenario
• Average Interference over Thermal Nose (avgIoT): Defines the operating point of the system.
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Receiver Dynamic Range The upper limit of 20 dBis targeted*.
Parameter Optimization in eNB-only Deployment
* B.E Priyanto et. al., "In-Band Interference Effects on UTRA LTE Uplink Resource Block Allocation," VTC Spring 2008, IEEE , no., pp.1846-1850, 11-14 May 2008
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Selected Parameter Settings
Cell coverage oriented Cell capacity oriented
Alpha 1.0 0.6
P0 -101 dBm -55 dBm
Average IoT 10.0 dB 13.5 dB
Cell capacity 9576 kbps 12670 kbps
Cell coverage 3536 kbps 2444 kbps
32% Capacity Increase
31% Coverage Loss
Parameter Optimization in eNB-only Deployment
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Apply toRelay
deployment
Step 2:
InfoPoint
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0 500 1000 1500 2000 2500 3000 3500 4000 45000
0.1
0.2
0.3
0.4
0.5
0.6
0.7
0.8
0.9
1
CD
F
Throughput per UE [kbps]
eNB-only with FPCFPC @eNB & FPC @RNsFCPC @eNB & FCPC @RNs
Applying eNB-only Parameter Settings• Throughput Distribution at Sector
Curves go to 1 at very high throughput
The optimal parameter settings obtained in eNB-only deployment are assumed also for relay deployment.
• NOTE: Although the relay link is considered ideal, 5%-ile user TP will not be affected from the non-ideal relay link.
Parameter Optimization in Relay Deployment
138% TP increase
186% TP increase
• Relay deployment outperforms eNB-only.•Parameter settings can be re-adjusted to further improve the performance.
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Step 3:
Optimization atRNs
InfoPoint
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Optimization at RNs (for FPC): Interference Mitigation• The effect of reducing power levels on the interference proportions. By means of decreasing Pmax and P0 @ RNs, the interference caused by relay users can be decreased significantly.
Parameter Optimization in Relay Deployment
Total IoT at eNB vs. P0RN
eNB-only setting for FPC
avgIoT=avgIoTmUEs+avgIoTrUEs-1
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Optimization at RNs (for FPC) : Receiver Dynamic RangeParameter Optimization in Relay Deployment
• Receiver Dynamic Range of RN
High receiver dynamic range for no power control
scheme.
Further decrease of Pmax,RN results in
higher receiver dynamic range at
RN.
Iso-performance schemes which
impose similar rUE interference.
Optimum Scheme Reduced max Tx
power is desirable for better battery
life time.
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Step 4:
Optimization ateNB
InfoPoint
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Performance Metrics
• Cell Coverage: 5th %-ile user throughput multiplied by the number of users per sector.
TP5%-ile
Cell Coverage =
TP5%-ile * numUE
• 50%-ile User Throughput: 50th %-ile user throughput multiplied by the number of users per sector.
TP50%-ile50%-ile user TP =
TP50%-ile * numUE
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Further Optimization: Tuning Parameters at eNB• Performance Metrics: 50%-ile User Throughput vs. Cell Coverage
Pre-optimizedeNB-onlysetting
Pre-optimizedeNB-onlysetting
Cell CoverageOptimized
50%-ile user TPOptimized
Parameter Optimization in Relay Deployment
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Further Optimization: Tuning Parameters at eNBParameter Optimization in Relay Deployment
Parameters50%-ile user TP
OrientedCell Coverage
Oriented
eNBs RNs eNBs RNs
P0 [dBm] -53 -61 -95 -101
alpha 0.6 0.6 1.0 1.0
Pmax [dBm] 23 15 23 15
TP gain w.r.t. eNB-only
@ 50%-ile 164% 122%@ 5%-ile 178% 204%
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Downlink Performance Evaluation
~ RN Coverage Extension ~
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Simulation ResultsRN deployment - ISD 500m
Significant gains from RN deployments
4 RN 10 RNs
Throughput Gain [%]
(Reference:eNB-only )
5%-ile 65 145
50%-ile 139 275
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Simulation ResultsRN deployment - ISD 1732mHuge gains from RN deployment in Suburban environments
4 RN 10 RNs
Throughput Gain [%]
(Reference:eNB-only )
5%-ile 194 541
50%-ile 267 612
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Further Improvement in the Downlink
?
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Motive
Relays are small nodes with low transmission power, and hence, small coverage areas.
Motive– Inefficient use of resources in the under-loaded RN cell– High competition on resources in the macro cell
Cost-free SolutionIncrease RN coverage area through biasing in cell selection and handover
thresholds.
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Balancing cell loads
• Default: Cell is selected according to received signal strength.• Adding a bias in cell selection and handover thresholds
increases the RN cell area, and hence its load.• UEs, which moved to the RN cell, will face less competition
on resources.
RN coverage area if cell selection according to signal strength
RN coverage area if X dB bias towards the RN
Distance from eNB
Rec
eive
d po
wer
Received power from the RN
Received power from the eNB
X dB biastowards the RN
RN coverage area if cell selection according to signal strength
RN coverage area if X dB bias towards the RN
Distance from eNB
Rec
eive
d po
wer
Received power from the RN
Received power from the eNB
X dB biastowards the RN
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Simulation ResultsBiasing - ISD 500m
Significant gain from 3dB biasing in cell selection
RN bias 3dB 6dB
5%-ile Throughput Gain [%]
Reference: No bias in cell selection
4 RNs 29 27
10 RNs 36 26
50%-ile Throughput Gain [%]
Reference: No bias in cell selection
4 RNs 6.5 8.5
10 RNs 3 6.5
Bias
SINR limit
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Simulation ResultsBiasing - ISD 1732m
Moderate gain from 6dB biasing in cell selection
RN bias 3dB 6dB
5%-ile Throughput Gain [%]
Reference: No bias in cell selection
4 RNs 5.5 6.5
10 RNs 8 8.5
50%-ile Throughput Gain [%]
Reference: No bias in cell selection
4 RNs 1.1 1.1
10 RNs 2.5 2.7
Bias
SINR limit
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Conclusions
• Relay deployments enhance system performance.
• Power control parameter optimization offers significant improvement in the uplink.
– Power control in relay deployment is a good means to mitigate interference, and to abide by the dynamic range limitations.
• RN coverage area extension offers further improvement in the downlink.
– RN cell extension via biasing in cell selection offers significant gains in ISD 500m scenarios.
– Biasing cell selection in ISD 1732m scenarios results in moderate gains.
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Thank you foryour
attention! Q & A
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Interference Proportions • Interference caused by Cell Center UEs and Cell Edge UEs can be analyzed separately.
NNIIoT linear
+=
~~
NNII rUEsmUEs ++
=~~
NNNNII rUEsmUEs −+++
=~~
1~~
−+
++
=N
NIN
NI rUEsmUEs
1~~~
−
+
=
⇒ rUEsmUEs IoTEIoTEIoTE
ImUEs and IrUEs are two independent random
variables.
~~
Parameter Optimization in Relay Deployment BACK-UPBACK-UP