January 2005
AIRCOM International 2005
3G RF Optimisation Basics
Robert Joyce
January 2005
AIRCOM International 2005
WCDMA Basics
▪ Frequency Reuse▪ Scrambling Codes▪ Signal Strength/Quality Measurements in WCDMA▪ Soft/Softer Handover▪ Pilot Pollution▪ Missing Neighbours
January 2005
AIRCOM International 2005
UK 3G Spectrum Allocations
From (MHz) To (MHz) From (MHz) To (MHz) From (MHz) To (MHz)A Hutchison 3G 1920.0 1934.9 2110.3 2124.9 1914.9 1920.0 2x15 + 5 = 35B Vodafone 1944.9 1959.7 2134.9 2149.7 N/A N/A 2x14.8 = 29.6C O2 1934.9 1944.9 2124.9 2134.9 1909.9 1914.9 2x10 + 5 = 25D T-Mobile 1959.7 1969.7 2149.7 2159.7 1899.9 1904.9 2x10 + 5 = 25E Orange 1969.7 1979.7 2159.7 2169.7 1904.9 1909.9 2x10 + 5 = 25
Total (MHz)TDD
Licence OperatorFDD DownlinkFDD Uplink
19051910 1960
FDD Uplink
Licence A - Hutchison 3GLicence B - Vodafone
1935
Licence C - O2
Licence D - T-Mobile
FDD Downlink
21502110
Licence E - Orange
19151920 1980 21251945 1970 2135 2160
TDD
January 2005
AIRCOM International 2005
Frequency Reuse
▪ Initially operators have been launching with just a single carrier▪ Vodafone NZ Network will initially be FDD only▪ Vodafone will launch using only the FDD carrier (F1 =10588)▪ All launch cells will use F1 & therefore Vodafone NZ’s 3G network
will have a frequency reuse of 1
UARFCNFrequency
(MHz)FDD Uplink F1 9638 1927.6
F2F3
FDD Downlink F1 10588 2117.6F2F3
January 2005
AIRCOM International 2005
Scrambling Codes & CPICH
▪ The Common Pilot Indication Channel (CPICH) is broadcast from every cell
▪ It carries no information and can be thought of as a “beacon”constantly transmitting the Scrambling Code of the cell
▪ It is this “beacon” that is used by the phone for its cell measurements for network acquisition and handover purposes (Ec, Ec/Io).
CPICH
January 2005
AIRCOM International 2005
3G Coverage Measurements
▪ The majority of 3G coverage measurements are based upon measurements of the CPICH
▪ Golden Rule: If the UE can’t see the CPICH the UE can’t see the cell.
▪ Initial 3G network optimisation will be performed purely from CPICH measurements
▪ Three key related measurements for 3G optimisation are
▪ Ec - The Received Signal Level of a particular CPICH (dBm)▪ Io - The Total Received Power (dBm)▪ Ec/Io - The CPICH Quality (The ratio of the above two values)
January 2005
AIRCOM International 2005
Total Received Power Io
▪ In a WCDMA network the User Equipment (UE) may receive signals from many cells whether in handover or not
▪ Io* = The sum total of all of these signals + any background noise (dBm)
▪ *Note: Sometimes Io is referred to as No, RSSI or ISSI
Io
January 2005
AIRCOM International 2005
Received Power of a CPICH Ec
▪ Using the properties of SCs the UE is able to extract the respective CPICH levels from the sites received
▪ Ec* = The Received Power of a Particular CPICH (dBm)
▪ *Note: Sometimes Ec is referred to as RSCP
Ec1 Ec2
January 2005
AIRCOM International 2005
The CPICH Quality (Ec/Io)
▪ From the previous two measures we can calculate a signal quality for each CPICH (SC) received
▪ Ec/Io = Ec - Io (dB)
▪ *Note: Sometimes Ec/Io is referred to as Ec/No
Ec1 Ec2
January 2005
AIRCOM International 2005
Example
▪ From the above three measurements we can calculate for each pilot the Ec level for that particular pilot
▪ Ec1 = -80 - 5 = -85dBm▪ Ec2 = -80 - 10 = -90dBm
Ec/Io1=-5dB Ec/Io2 =-10dB
Io=-80dBm
January 2005
AIRCOM International 2005
Ec, Io and Ec/Io Measurement
▪ All commercial scanners and test UEs are capable of making Ec, Io and Ec/Io measurements
▪ It is these measurements that are used for cover analysis and basic optimisation
January 2005
AIRCOM International 2005
3G Scanners
▪ Many types of 3G scanners on the market▪ Agilent’s 3G Scanner & Nitros Software▪ Anritsu’s ML8720B 3G scanner▪ DTI Seagull (Dual band 3G/2G) scanner
▪ From experience the Anritsu scanner is the better of the all three with a higher sampling rate and greater flexibility
▪ However DTI scanner has added benefit of 2G scanning, ideal for 3G-2G neighbour optimisation as well as 2G optimisation
January 2005
AIRCOM International 2005
Handovers in WCDMA
▪ Various handover types exist in WCDMA
▪ Those between WCDMA sites (intra-system HO)▪ Those between WCDMA and GSM (inter-system HO)
January 2005
AIRCOM International 2005
Handovers in WCDMA - Softer HO
▪ Softer handover occurs between sectors of the same site
January 2005
AIRCOM International 2005
▪ Soft handover occurs between sectors of the different sites
▪ For both softer and soft it is the Ec/Io levels used to determine whether a cell should be added or removed from the active set
Handovers in WCDMA - Soft HO
January 2005
AIRCOM International 2005
Handovers - Inter frequency HO
▪ Inter frequency handover occurs between two WCDMA carriers▪ Will be used once operator deploys its second carrier, for microcell
layer or capacity purposes
January 2005
AIRCOM International 2005
Handovers - Inter system HO
▪ Inter system handover occurs between 3G and 2G sites▪ As with all handovers, accurate adjacencies will be required
3G 2G
January 2005
AIRCOM International 2005
Optimisation Basics
▪ Coverage Optimisation▪ Neighbour Optimisation▪ Pilot Pollution Optimisation▪ SHO Optimisation
January 2005
AIRCOM International 2005
Coverage Optimisation
▪ As with 2G if the coverage is inadequate then the call quality will be inadequate
▪ Therefore this first stage in 3G optimisation is ensuring adequate coverage
▪ Link budgets should be used to determine both the planning targets and the drive survey level targets
▪ Note that the planning and drive survey level targets will be different
January 2005
AIRCOM International 2005
Coverage Optimisation
Dense Urban Urban/Suburban Rail Road Rural IndoorDeep Indoor - 95% Deep Indoor - 95% Indoor Window - 95% Indoor Window - 95% Outdoor - 90% 95%
12.2k Speech -71.0 -81.0 -88.0 -95.0 -102.0 -102.064k CSD -72.0 -82.0 -90.0 -96.0 -103.0 -102.064k PSD -73.0 -82.0 -90.0 -97.0 -103.0 -103.064k CSD Videophone -71.0 -80.0 -88.0 -94.0 -101.0 -101.0144k CSD -69.0 -79.0 -86.0 -93.0 -100.0 -99.0144k PSD -70.0 -79.0 -87.0 -94.0 -100.0 -100.0384k CSD -65.0 -75.0 -84.0 -90.0 -95.0 -95.0384k PSD -66.0 -76.0 -84.0 -90.0 -96.0 -96.0
ServiceEnvironment
▪ These levels are the levels that should be achieved at the roof of the vehicle
▪ If these levels are not achieved then inbuilding coverage will be poor▪ Further optimisation with lower coverage levels is very difficult▪ Solutions: Downtilt, Azimuth, New Site
▪ Given below are example target drive survey Ec levels for the different 3G services
January 2005
AIRCOM International 2005
Neighbour Optimisation
▪ Missing Neighbours was and still is the biggest cause of poor performance in most commercial 3G networks
▪ The majority of call drops in early cluster are due to missing neighbours.
▪ It is therefore essential that the initial neighbour list is thorough, ideally with neighbours ranked in order of importance
▪ In 3G the UE must be on the best cell at all times … otherwise it will drop the call – this is not the case in 2G
▪ 3G/2G neighbour lists must also be comprehensive, incorrect 3G/2G neighbour lists will lead to dropped calls when moving from 3G to 2G and poor 3G re-selection performance when on 2G
January 2005
AIRCOM International 2005
3G/3G Neighbour Optimisation
▪ We declare a 3G missing neighbour as a a cell not declared as neighbour of the best active cell although it is eligible to be added in the active set.
▪ A practical margin of 5dB is recommended as an initial window …anything bigger and the neighbour lists become too large
▪ Solution: 3G Scanner Survey, Actix Analysis, Neighbours Added
NMISSINGBESTNMISSING inMEcNoEcNo __ arg−≥
January 2005
AIRCOM International 2005
2G/3G Neighbour Optimisation
▪ 2G/3G neighbour optimisation will require the use of both 3G and 2G drive survey equipment
▪ Dualband scanner files can quickly be processed to pair up the best 3G cells with the best 2G cells for every sample along the drivesurvey.
January 2005
AIRCOM International 2005
Pilot Pollution Optimisation
▪ As more and more 3G sites are integrated, the pilot pollution within the network will increase
▪ With >4 pilots of a similar level it can be very difficult to establish even a voice call
▪ The higher the data rate the more susceptible the service is to pilot pollution (bad Ec/Io).
▪ Whilst 3G voice requires an Ec/Io of above -15dB, 384kbps will required Ec/Io levels of -9dB or higher !!
▪ Pilot pollution should not be confused with poor coverage, where there is poor coverage, there is generally pilot pollution/bad Ec/Io
January 2005
AIRCOM International 2005
PS384 - Pilot Pollution Areas
▪ DL_PS384 is much more sensitive to pilot pollution or overlaps than lower bit-rates. Optimising pilot pollution for PS128 is already a challenge, for 384 might be an unrealistic target.
▪ Comparison of required EcIo:
Service Voice PS64 PS128 PS384Min EcIo -15 -13 -13 -9.5
▪ Even with good Ec levels, some areas will never provide reliablePS384 simply due to cell overlaps. It seems unclear whether a mature network may ever provide a full 384 footprint.
Conclusion: 384 requires an optimised network
January 2005
AIRCOM International 2005
Required EcIo
GPRS Attach Success Rate vs Serving CPICH Ec/Io
-20%
0%
20%
40%
60%
80%
100%
120%
-19 -18 -17 -16 -15 -14 -13 -12 -11 -10 -9 -8 -7 -6 -5
Serving Cell CPICH Ec/Io (dB)
GPRS Attach Success Rate
January 2005
AIRCOM International 2005
PS384 - required EcIo
DL Application Throughput vs. Serving Cell CPICH Ec/Io
0
50
100
150
200
250
300
-14 -12 -10 -8 -6 -4 -2 0Serving Cell CPICH Ec/Io (dB)D
L A
pplic
atio
n Th
roug
hput
(kbp
s)
Mean DL Application Throughput
Mode DL Application Throughput
DL Application Throughput (Last Value)
January 2005
AIRCOM International 2005
Pilot Pollution Optimisation
▪ To avoid confusing areas of poor coverage with areas of pilot pollution we can define an area of pilot pollution as somewhere where
▪ The Ec target is the target coverage = -100dBm▪ The current recommended Ec/Io target = -10dB▪ Actix is able to identify areas of pilot pollution and display the locations
on a map
Best server CPICH_Ec >= Ec target (dBm)
And
Best server CPICH EcNo < Ec/Io target (dB)
January 2005
AIRCOM International 2005
Pilot Pollution Optimisation
▪ There are various means of reducing pilot pollution▪ New Sites: Additional sites may reduce pilot pollution by bringing
dominance to an area (before optimising for pilot pollution, always check that a new site is not about to be brought on air in the locality)
▪ Antenna Downtilts: By adjusting tilts on the best servers, or worst interferers, pilot pollution can be removed
▪ Solution: 3G Scanner Survey, Analysis, Downtilts, New Sites?
January 2005
AIRCOM International 2005
Handover Optimisation
▪ Softer, Soft, Inter-frequency & system HOs have all been optimised on Nokia’s trial and other customers networks
▪ Therefore initial HO Optimisation should not require any changes to the UTRAN parameters ….
▪ Instead initial HO optimisation will involve studying how much HO occurs in the network and where this HO occurs.
▪ For 3G/3G HO, Actix is able to display areas where Softer & Soft HO is occurring and calculate the percentage of a drive route in SHO
▪ Typically we should be aiming for a SHO area of less that 40%▪ Optimisation of SHO area should be performed using downtilt and
azimuth changes▪ Solution: 3G Scanner Survey, Analysis, Downtilt and Azimuth
changes
January 2005
AIRCOM International 2005
Optimisation Basics
▪ Coverage Optimisation▪ Neighbour Optimisation▪ Pilot Pollution Optimisation▪ SHO Optimisation
▪ Everything is based around Ec/Io, to improve this we need to
▫ Increase Ec (improve the best server(s))▫ Reduce Io (reduce pilots not eligible for the active set)▫ Get all neighbours optimised
▪ In call drive runs should only take place once Radio Optimisation is complete
January 2005
AIRCOM International 2005
Overview of Vodafone New Zealand Optimisation Process
January 2005
AIRCOM International 2005
OrangeUK 3G Optimisation Process
▪ This section will cover the following;
▪ Overview of Vodafone New Zealand 3G Optimisation Process▪ Key Performance Indicators▪ Analysis Tools & Processes▪ Next Steps
January 2005
AIRCOM International 2005
Overview of Vodafone NZ’s 3G Optimisation Process
▪ Based upon the 3G Optimisation Process flowcharts agreed between Aircom/Nokia and Vodafone New Zealand
1 hour prior to every cluster Drive test 3G Opt eng must
obtain CDF dump from OSS eng
CDF file obtainable ?
3G Opt eng obtains Alarm report and cell availability
report from OSS eng
Yes
No
CDF = Cell Definition File
Yes
Check with Nokia Opt manager
High number of alarm ?
Can drive testproceed ?
Yes
No
Can drive testproceed ?
Check with Nokia Opt manager
Yes
High cell availability ?
No Check with Nokia Opt manager
Yes Yes Can drive teststart ?
Can OMC solve the problem < 4
hours?
Yes
OMC works onsolving the alarm
Is the problem solved ?
No
Optimization Stage 1(Optimize RF condition)
Optimization Stage 2(Optimize Neighbour list)
Optimization Stage 3(Optimize Call Performance)
Postpone the drive testto next day or until
Problem solved
Can OMC solve the problem < 4
hours?
Yes
OMC works onIncreasing cell
availability
Is the problem solved ?
No
Stage 1 completed?
Stage 2 completed?
Stage 3 completed?
KPI measurementand reporting
Postpone the drive testto next day or until
Problem solved
No
No
No
Yes
Yes
Yes
No
No
NoNo
Yes
Yes
A
A
A
A
D
C
B
Drive test starts
A.1
A.3A.2
A.4
A.5
A.6 A.7
A.8A.9
A.10
A.11A.12
A.13A.14
A.15
A.16A.17
A.19
A.21
A.22
A.20
A.23
A.24
A.18
January 2005
AIRCOM International 2005
Overview of Vodafone NZ’s 3G Optimisation Process
▪ Based upon the 3G Optimisation Process flowcharts agreed between Aircom/Nokia and Vodafone New Zealand
▪ Stage 1 & 2 cover the basic RF Optimisation steps described earlier
▪ Only once these steps are completed is it worth moving onto Stage 3 – Call Performance Optimisation
Yes
Optimization Stage 1(Optimize RF condition)
Optimization Stage 2(Optimize Neighbour list)
Optimization Stage 3(Optimize Call Performance)
Stage 1 completed?
Stage 2 completed?
Stage 3 completed?
KPI measurement
No
No
No
Yes
Yes
Yes
A
A
A
D
C
B
Drive test starts A.8
A.10
A.14
A.17
A.22
A.20
A.23
A.24
January 2005
AIRCOM International 2005
Key Performance Indicators (KPI)
▪ In order to benchmark the performance of a 3G network a basic set of KPI targets are required
▪ The Vodafone NZ 3G KPI targets fall into two categories, RF KPIs and in-call KPIs
▪ The Vodafone RF KPIs are very simple and concise but focus on the key RF requirements of Ec (RSCP), Ec/Io and SHO area
▪ The In Call or End To End (E2E) KPIs are somewhat more complex
January 2005
AIRCOM International 2005
Vodafone RF KPIs▪ The RF targets are defined in terms of: -
▫ RSCP of the Common Pilot Channel▪ -89 dBm in >= 95% of bins for dense urban▪ -94 dBm >= 95% of bins for urban▪ -99 dBm >= 95% of bins for suburban▪ -104 dBm >= 90% of bins for rural
▫ Ec/Io of Common Pilot Channel in unloaded network▪ Ec/Io >= –10 dB in >= 95% of bins for DU, U, SU▪ Ec/Io >= –10 dB in >= 90% of bins for Rural
▫ Ec/Io of Common Pilot Channel in loaded network▪ Ec/Io >= –14 dB in >= 95% of bins for DU, U, SU▪ Ec/Io >= –14 dB in >= 90% of bins for Rural▪ Test case to be agreed
▫ SHO Overhead: 30-40%▪ This Kpi will be measured according to the formula below:
SetActiveinCellsBinsSetActiveinCellsBinsSetActiveinCellBinsSetActiveinCellsBinsSetActiveinCellsBinsSetActiveinCellBins
____3__#____2__#____1__#3____3__#2____2__#1____1__#
++×+×+×
January 2005
AIRCOM International 2005
RF Optimisation
▪ Basic RF analysis checking the following
▪ Coverage Optimisation▪ Neighbour Optimisation▪ Pilot Pollution Optimisation▪ SHO Optimisation.
▪ First stage is to run the KPI reports, then follows this with more detailed analysis.
▪ If the route meets the RF KPIs there’s no point doing further analysis
January 2005
AIRCOM International 2005
Actix RF KPI Report
▪ Run the basic RF KPI report – check the KPIs
January 2005
AIRCOM International 2005
Basic “Sites on air” analysis
▪ For each cell in the cluster check that coverage is seen for the sites expected to be on air
▪ Check correct SC is radiating in the expected direction (crossed feeders?)
▪ Highlight those sites not seen on air and any suspected crossed feeders
▪ But make sure your cell refs data is accurate !!!
January 2005
AIRCOM International 2005
Coverage (Ec) Analysis
▪ If KPI Report indicates good Ec - no further Ec analysis required !▪ Otherwise analyse !!▪ Solution: Tilts, azimuths, new sites
January 2005
AIRCOM International 2005
Neighbour Optimisation
▪ If downtilts are to be made to any sectors, then additional neighbours should not be added to/or for these cells as they may not be necessary after downtilts
▪ Actix should be used to generate Missing Neighbour Report from Scanner data
▪ Remember until the cluster is complete, additional neighbours will come and go
January 2005
AIRCOM International 2005
3G/3G Neighbour Optimisation (2)
▪ 3G Neighbour lists can be generated automatically by the Actix
▪ The tool runs through every point in the survey comparing the Ec/Io values of the SCs seen generating a neighbour list like the one given
▪ The number of missing neighbours found will be dependent on the quality of the initial neighbour list
▪ Don’t be scared of adding neighbours !!
sc neighbour count8 9 1658 232 528 496 408 344 348 154 188 386 128 10 118 362 118 145 108 114 88 256 58 488 58 360 48 376 48 346 38 50 18 218 18 490 18 66 18 152 18 48 18 378 18 401 19 8 1149 362 379 10 10
January 2005
AIRCOM International 2005
Pilot Pollution (Ec/Io) Analysis
▪ Run Pilot Pollution query to display areas of pilot pollution on map
January 2005
AIRCOM International 2005
Pilot Pollution (Ec/Io) Analysis
▪ Identify worst “Pilot Polluters” on map▪ Solution: tilts, azimuths, new site?
January 2005
AIRCOM International 2005
SHO Analysis
▪ KPI report will indicate % of route in SHO▪ Aim for SHO < 40%▪ Run RE SHO query to display areas on a map - is this due to distant
sites, is it in important high traffic areas?▪ Solution: Tilts, Azimuths
January 2005
AIRCOM International 2005
Cell Adjacency Planner - CAP3G – 2G Adjacencies
January 2005
AIRCOM International 2005
Cell Adjacency Planner - CAP3G – 3G adjacencies
January 2005
AIRCOM International 2005
3G/3G Neighbour Optimisation (3)
January 2005
AIRCOM International 2005
Stage 3: In Call Optimisation
▪ Only once the RF Optimisation is complete should In Call analysis be undertaken
▪ In call analysis will also pick up▫ Coverage Problems▫ Pilot Pollution Problems▫ Missing Neighbours▫ SHO problems
▪ However if the RF Optimisation has been done correctly, none of the above should be seen at Stage 3 !
▪ In Call Optimisation will be similar to RF Optimisation▫ Run In Call KPI report▫ Analyse any problems seen
January 2005
AIRCOM International 2005
Stage 3: Run Call KPIs Report
▪ Run RE Call KPI report▪ Identify problem areas, Call Setup Success, Call Drop etc.
January 2005
AIRCOM International 2005
Stage 3: Detailed In call analysis
▪ Detailed in call analysis▪ Look for the basics first, Ec, Ec/Io, missing neighbours etc.▪ Only then delve into the detailed L3 message flows.
January 2005
AIRCOM International 2005
Process Summary
▪ Stage 0 Cluster Preparation - plots, site checks, neighbour checks etc.
▪ Stage 1&2 RF optimisation, Ec, Ec/Io, Missing Neighbours, SHO Area
▪ Stage 3 In Call Analysis (Speech, Video, PS, ISHO etc) – will be the subject of a further training session once Actix Reports in place.
▪ CLUSTER ACCEPTANCE !!
▪ Any questions: [email protected]
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